Difference between revisions of "Common plugs and connectors"
m (→PLCC (Plastic Leaded Chip Carrier))
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====PLCC (Plastic Leaded Chip Carrier)====
====PLCC (Plastic Leaded Chip Carrier)====
PLCC chips be seated in a PLCC socket (can be handy for replacement ability, or when heat is critical), surface-.
Was also used in early CPUs, after DIP and before more specialized sockets.
Was also used in early CPUs, after DIP and before more specialized sockets.
====Micro Leadframe, Flat No-lead====
====Micro Leadframe, Flat No-lead====
Revision as of 17:40, 29 June 2022
Yes, this is largely biased to the stuff I deal with.
Ideally 'common' is true enough. Suggestions are welcome.
- 1 Mixed use (analog, digital, home electronics, audio)
- 2 Video cables/plugs
- 2.1 Composite video
- 2.2 Component video (YPbPr)
- 2.3 S-Video
- 2.4 SCART
- 2.5 VGA
- 2.6 D-Terminal
- 2.7 Digital video cables (high speed and/or uncompressed)
- 3 Audio(-only)
- 4 Computer
- 4.1 Power supply
- 4.2 Fan connector
- 4.3 Storage
- 4.4 USB
- 4.5 8P8C / Ethernet cable
- 4.6 Firewire (IEEE 1394)
- 4.7 Thunderbolt
- 4.8 PS/2
- 4.9 D-sub (D-subminiature)
- 4.10 Ribbon-cable-and-IDC
- 4.11 Micro ribbon
- 5 Mobile devices
- 6 Memory cards
- 7 RF/coax connectors
- 8 Power - device side
- 8.1 Low/medium voltage, device side
- 8.1.1 DC connectors, EIAJ power, coaxial and more
- 8.1.2 3-Pin and 4-Pin DC Plugs
- 8.1.3 More specialized
- 8.2 Mains power, device side
- 8.1 Low/medium voltage, device side
- 9 Mains power - wire-to-wire connectors
- 10 Power - wall plugs
- 10.1 Type A, Type B, household NEMA variants, JISC C 8303 Class II
- 10.2 Type F / Schuko / CEE 7/4
- 10.3 CEE 7/7 plugs
- 10.4 Other, non-earthed European plugs: Type C, CEE 7/16, CEE 7/17, Europlug
- 10.5 Type E
- 10.6 Type G, BS 1363 (UK)
- 10.7 Type I
- 10.8 Type N
- 10.9 Type H
- 10.10 Type J
- 10.11 Type L
- 10.12 Type K
- 10.13 Type D, M
- 10.14 Type O
- 10.15 When does wall polarity matter?
- 11 Power - industrial and multiphase interconnects
- 12 Lightbulbs
- 13 Specialist
- 14 Low power or signals
- 14.1 Testing things
- 14.2 Smaller JST connectors
- 14.3 Smaller molex connectors
- 14.4 Smaller AMP connectors
- 14.5 Circular metric
- 15 Mounts, chip carriers, packages, board connectors
- 15.1 Mounts, chip carriers
- 15.1.1 On pitch
- 15.1.2 SMD/SMT versus though-hole
- 15.1.3 Packages, roughly from fewer to more leads
- 15.1.4 DO
- 15.1.5 See also
- 15.1.6 Unsorted chip mounts
- 15.2 PCB connectors
- 15.3 Moderately narrow-use but not single-use
- 15.1 Mounts, chip carriers
- 16 Unsorted
Mixed use (analog, digital, home electronics, audio)
TRS (Tip, Ring, Sleeve) and variations
'TRS' may be clearer when distinguishing it from plugs in similar use, but the everyday names we use are more specific - and somewhat regional.
The 3.5mm is often known as headphone jack, mono jack or stereo jack, and sometimes things like mini jack, mini-phone.
The 6.35mm was classically called phone connector (though telephone jack may refer to modular connectors instead), now largely associated with guitar wires.
The history of plugs like these is complex, and there are some leftovers today that use less usual variants.
But what you're most likely to meet is primarily:
- The 1/4", which is precisely 6.35mm
- Americans refer to it as 1/8" (0.125") though it's more like 0.138"
- best known for three-band (TRS) in headphones for stereo sound, used that way for a few dozen years, and often referred to as audio jack, mini-jack, jack plug, stereo plug, and others. Sometimes phone connector but that suggests the 1/4" one
- Americans refer to it as 3/32" (0.09375") though it's more like 0.098"
The 1/4 size is standardized by an inch size because of its phone network origins(verify),
...while 2.5mm and 3.5mm are standardized by millimeters, so the inches are approximations there. (it seems they're always manufactured to mm sizes, so the inch figures are just names)
TS, TRS, TRRS
The original 1/4" had two contacts, so had a tip and sleeve (TS).
It grew more bands over time, so e.g. 3.5mm is frequently seen in TS, TRS, and occasionally TRRS. TRRRS exists but is rare.
3.5mm TRRS is
- is probably mostly associated with having headphones that include a microphone, around smart phones.
- has some other uses, like carrying analog video and audio on one plug
- the sleeve is typically ground
- 3.5mm TRS for sound
- tip: left
- ring: right
- sleeve: ground
- 6.35mm TRS
- sturdier variant of 3.5mm, same level and pinout
- balanced audio (pro audio)
- some variants around mixers (pro audio)
- TRRS for headphone, mic and/or buttons []
- The general standard: Left Right Mic Ground (OMTP)
- Apple being different: Left Right Ground Mic (CTIA)
- TRRS - audio and analog video, such as
- iPod's AV cable (Left Right Ground Video)
- raspberry pi audio+video (same pinout)
- there are variants of this. It's handy to have adapters with RCA, in that sometimes you can get around variations by plugging things differently
The buttons don't need extra wires in a TRRS plug because they'll be using different resistor values between mic and ground pins.
0..70 ohm Function A, play/pause/takecall 110..180 ohm Function D, typically voice commands 210..290 ohm Function B, volume up 360..680 ohm Function C, volume down
(The impedance of the microphone itself is considerably higher, and sense-wise acts as the default)
~0 ohm is play/pause/takecall
Other things seem to be proprietary signaling, which allows them to add functionality over time. And piss of imitators, and DIYers.
Used for audio, video (often composite, now also component), some simple data (like non-optical digital audio)
Named for its introduction by the Radio Corporation of America.
Other names include cinch connector, phono connector, and some odd ones out like the Dutch calling it a tulpstekker (after tulips, because of course).
DIN refers to a whole standardization body.
"DIN connectors" typically refers to members of a specific series of circular plug/sockets, that have a 13.2mm-diameter round metal friction locking shield.
These come from at least five different DIN standards.
It seems said original DIN standards are out of print, and you now want to read IEC 60130-9, which also expanded the series (verify))
Being an existing, relatively sturdy, relatively versatile, and relatively cheap style of connector, these once saw a lot of varied use, be it digital (e.g. MIDI, AT keyboard connector), audio/video (e.g. tape decks, microphones), and sometimes power.
Many of them were fairly specific to brands or devices (e.g. Commodore 64 uses 7-pin for power, and 8-pin (5-pin in a few early models) for audio and composite video).
Many such uses have since grown more specific connectors. Which is probably good, to avoid smoky mistakes from too many distinct uses sharing a plug.
The only one that survived a lot longer in wide use is MIDI.
- DIN 41529: 2-pin, historically seen in loudspeakers, though I've also seen them used for low voltage lighting
Look a bit like
Mini-DIN is a similar-looking variation also from DIN, with a 9.5mm round metal shield. Additionally uses plastic slots that makes plugging into other variants hard without a hammer.
S-video on the back on a SCART adapter
Probably best known for
Other uses include audio, video, some communication, and some fairly one-off video card adapters back when analog video was still a thing we wanted. I've also seen some used for power.
You should assume each connector has multiple, unrelated uses before you plug something in.
There are a number of have the same 9.5mm housing as mini-DIN, but are not standardized or approved by DIN.
Some are designed to be compatible with specific standard mini-DIN (e.g. to have a video card socket that accepts both standard S-Video plug but also its own connects-more-stuff variant).
Others are designed to be specifically incompatible with standard mini-DIN.
Modular connector (?P?C); Registered Jack
Modular connector (when it refers to a specific connector) were developed for phone uses but got used more widely.
Variations of socket and plug are named by
- how many positions there are (which also implies the plug/socket width), and
- how many conductors are actually present (filled out from the center positions).
For example, 6P2C has 6 positions and two conductors, 8P8C has 8 positions and has conductors in all positions.
The 2, 4, 6, 8 positions/lead connectors are mostly standard, 10P10C and further variations also exist.
Smaller plugs fit in larger sockets, e.g. 4P and 6P plugs fit in 8P sockets, and only in one position because the clip centers the plug.
Within some specific uses, this is intentionally designed for this to be useful and safe. In other cases, and more creative use, this doesn't help anything.
RJ meaning analog phone
There is some correlation/association between specific connectors and likely uses (in specific contexts). Consider for example
- 4P4C ~ RJ9 (mostly used to connect handsets to phones - two pairs, one for the microphone and one for the speaker)
- 6P2C ~ RJ11 (one-pair, one telephone line)
- 6P4C ~ RJ14 (two-pair, two telephone lines)
- 6P6C ~ RJ25 (three-pair, three telephone lines)
- 8P8C ~ RJ45 (sort of), and RJ49 (ISDN)(verify)
(For larger lists, see e.g. [Wikipedia: Registered_jack#List_of_official_types] ):
RJ45 meaning ethernet?
Technically, RJ45 refers to phone wiring (on 8P2C(verify)), and is almost completely unrelated to Ethernet.
Practically, within the computer world RJ45 refers to 8P8C connectors wired for Ethernet, to the point that it's actually hard to do a web search for the original phone wiring.
A further reason for confusion is that for a time, you could use the same wiring, and even the same 8C8C socket socket, to do a single analog phone line, and 100MBit Ethernet, because
- 6P2C plugs into 8P8C sockets fine and would use the center two pins
- 100BASE-TX (and 10BASE-TX) would use four of the other pins
- Ethernet cables of the time typically wired all four pairs anyway (of which two were rarely used)
This was never ideal in that it could lead to some pricy mistakes, and now less common as there is no such free pair in the now-standard 1000BASE-T, and office phones are now often VoIP anyway.
Less standard ?P?C uses
- http://en.wikipedia.org/wiki/Registered_jack (telephone wiring)
|This article/section is a stub — probably a pile of half-sorted notes, is not well-checked so may have incorrect bits. (Feel free to ignore, or tell me)|
Composite video (not to be confused with component video)
Carries Y, U, and V with sync pulses, and is also easy to broadcast - it is almost entirely the same as analog TV's format. Video recorders and some early computers modulate such a signal onto a local video channel, on their antenna output wire.
The main upsides to composite is probably that it is easy to transfer video between devices with a simple, common plug.
The main downside is that it susceptible to various visual artifacts, including noise/interference, dot crawl, also depending on the quality of the encoding/decoding hardware.
Quality you get from composite video varies noticeably between different (types/qualities/designs of) devices, and you want to use only shortish cables.
Composite video can also be called CVBS, an acronym with various possible readings, depending on who you ask: "Color, Video, Blank and Sync", "Composite Video Baseband Signal", "Composite Video Burst Signal", or "Composite Video with Burst and Sync".
Component video (YPbPr)
Component video (not to be confused with composite video) could refer refer to any system that sends video in multiple separated channels, but specifically carries a YPbPr signal.
Typically on three RCA connectors, and for YPbPr these connectors are frequently red, green, and blue. (Green plug carries the Y signal (Luma), the blue the Pb (blue minus yellow), and the red the Pr (red minus yellow) signal)
...not to be confused with RGB video, which also exists, in multiple forms (and can be called component video in the wider sense)
S-Video (also Super Video or Separated Video, and also sometimes called Y/C) carries luma (Y) and chroma (C) signals on separate wire pairs, using standard 4-pin mini-DIN plugs.
It is similar to composite video in that it carries the same information, but avoids shoving the Y and C information together to be separated later with possibly cheap electronics, which can lead to lower quality video. Still, in fairly ideal conditions (for composite), S-Video is no better than composite.
S-Video-to-Composite-video converter cables can just join the wires (although this may mean the colors are less saturated - something about the voltage amplitudes of these two signals?(verify)).
Note that you can not use that same converter to go from composite to S-Video, as that would put a mixed Y+C channel on both the Y and C pairs. The S-video decoder hardware will usually partially understand this, which results in a black and white image(verify).
You may find video-related cables that resemble the 4-pin mini-DIN S-Video plug. This includes:
- a 9-pin variation called VIVO (Video In Video Out), seen on video cards, that allows S-Video in, S-Video out, component out, and composite out.
- I've seen some video cards come with a 7-pin plug. This is rarely a standard mini-DIN plug, and often has its plastic slot in the same place as on the 4-pin DIN plug, but wider, so that the video card socket will accept a standard S-Video plug, and also the plug on the cable supplied with the card which uses the extra pins to carry, usually, another type of video (often composite video, sometimes composite video).
- a different 7-pin connector (standard mini-DIN) used on some professional (VCR) kits
SCART (a.k.a. Euro AV, EIA Multiport) combines a bunch of analog audio and video formats used by various common plugs, making it somewhat easier to connect various common home devices.
Before HDMI, SCART was very common on VCRs, TVs, and also frequently seen on DVD players and such.
SCART can carry:
- Mono/Stereo Audio, both ways
- Composite video, both ways
- S-Video may be supported both ways, but isn't always implemented
- RGB (on newer hardware, by re-purposing some wires, so both ends need to support and both to specifically this (ab)use)
You can easily find adapters to one or more specific things, like RCA audio, composite video and/or and S-Video, and sometimes versions with a switch that selects whether you want to use the converter plug to act as input or output.
RGB is higher quality, but
- has to be supported by both sides
- can also not be used at the same time as S-Video output
- is only meant for player-to-display travel.
Supported primarily by some more modern TV sets (receiving role) and recent media players (sending role) although supporting players only use RGB when you explicitly configure them for it, for compatibility reasons.
- EN 50049-1
VGA can refer to an old video card that set a graphics standard, but later it mainly referred to the standard connector it uses, DE-15.
VGA made sense when monitors were CRTs and their scanning beam made them all-analog in nature. You had to convert it to analog somewhere, and they chose to do it in the graphics card.
On flatscreens, though, we have discrete pixels, meaning that now we had a digital image in the PC that we send in analog and then convert back to digital to put on those pixels. This is a weird situation and asking for signal losses. Which is why we moved on to digital communication for our monitors.
The 15-pin connector only really has five signals that are important enough to be required:
- hsync, vsync
- red, green, and blue pixel data
There's a bunch of ground pins, to give each signal its own ground ('return') and allowing twisted pair setups for lower interference(verify).
Four pins were reserved for DDC (Display Data Channel) to help PCs identify monitor capabilities.
- DDC saw a few schemes and protocols over time (including pulldown resistors, one-directional serial, I2C).
One pin is 5V to power the EEPROM used in some of these schemes, but is otherwise unused.
See also VGA hacking
D-Terminal (not to be confused with D-Subminiature a.k.a. D-Sub) is probably most common in Japan, and seen elsewhere mostly in specific applications, e.g. digital satellite tuners.
The wires carry component video, and signal lines that use logic-level voltages to signal the video's resolution, ratio, and whether it is interlace/progressive.
Can carry analog 480i through 1080p, varying with the actual devices
Breakout cables to component video over RCA and BNC exist.(verify)
Digital video cables (high speed and/or uncompressed)
|This article/section is a stub — probably a pile of half-sorted notes, is not well-checked so may have incorrect bits. (Feel free to ignore, or tell me)|
On digital and/or analog
DVI can carry both analog and digital video, but specific wires and interfaces can choose to do just one.
In the plugs, there is a plate on one side - if there are pins around that (red in the pinout image on the right), the cable can carry analog video.
If there are pins around that plate, it can carry analog video, and is DVI-A or DVI-I.
- if the nearest 3x3 pins are a full block, it's DVI-I (carries analog and digital)
- if not, it's DVI-A (carries only analog)
If there are at least two blocks of 3x3 pins, the cable can carry digital video.
- if there is no pins around the plate, it is DVI-D(carries only digitial)
- if there are pins around that plate, it is DVI-I
If everything is one solid block of pins (that is, includes the blue pins in the image on the right), it can do dual-link digital. If it's not full, it's single-link digital.
There are some other connectors that look roughly like DVI but are incompatible, such as:
- VESA P&D / M1-DA (an extension to DVI from VESA)
And two different many-pin connectors, often seen for many-monitor graphics cards, as each connector can be used for two monitors:
Needs an adapter for things like DVI or VGA (doesn't carry them directly). The absence of pin 58 in DMS-59 seems to be just for keying. It isn't used in LFH either(verify), so you can use DMS-59 cables where you would otherwise use LFH.(verify)
MiniVGA, MiniDVI, MicroDVI, Mini DisplayPort
- mainly seen in Apple hardware (mostly MacBooks) circa 2005(verify)
- not standardized, and died out fairly quickly
- replaced by Mini DVI (which could also go to VGA) and MiniDisplayPort (which does even more)
- mainly seen in Apple hardware (mostly MacBooks) circa 2005(verify)
- not standardized, and died out after a while
- didn't really support non-Apple converters to VGA
MicroDVI, again mostly Apple, was used on some Macbook Airs.
- confusable with USB ports.
- not standardized, and died out after a while
- There are adapters to VGA and to DVI-D (not DVI-A or DVI-I).
All of the above were discontinued circa 2010, in favour of Mini DisplayPort.
- Initially in Apple laptops, now adopted by VESA and used by other vendors
- There are converters to VGA, (Dual-Link) DVI, HDMI, Displayport, and probably more
- May also carry audio, may not.
Other Apple connectors
Intel and Apple developed Thunderbolt, which uses the same plug as Mini DisplayPort.
...which is intentionally backwards compatible but also potentially confusing,
- It's a more generic bus like USB, but the expectations of such are probably still mostly monitor-y.
- so e.g. the same Apple monitor will do more on one laptop than another.
It's safe to connect and will display, but any feature beyond that won't work.
You can tell by the logo:
- monitor-like logo → Mini DP
- lightning-bolt logo → Thunderbolt.
Note that Thunderbolt 3 uses the standardized USB-C (which is now entering general use), so mini-DP-style thunderbolt is now sometimes referred to as Thunderbolt 2 connector.
Thunderbolt is, by name, confusable with Lightning.
Lightning is the thin flat reversible plug with little strips of connector. It is almost exclusive to iPhone, iPad, iPod, and a handful of Apple accessories. It can do charging, USB data connection, video out, audio out, and apparently SD card reading(verify)
It is being displaced by USB-C, but rather slower than you might expect (possibly because of proprietary sales reasons).
High-Definition Multimedia Interface (HDMI) 
Digital transfer. Can carry HD video, and audio. Has hardware-level copy protection (HDCP).
There are plug variants.
- Type A is by far the most common, what you usually use
- Type B has more data lines, designed for very-high-bandwidth applications, but never got used. DisplayPort now make more sense in practice
- Type C is the mini variant (meant for small/mobile devices)
- Type D is the micro variant (meant for small/mobile devices)
- seen e.g. on Raspberry Pi 4
- Type E is an automotive variant - locks in place, more resistant to moisture and dirt
- you can also get type A in a harness, giving similar features while being compatible with existing cables
(For computers it can be relevant that HDMI can carry DVI-D fairly directly - though this will probably only work if the DVI device supports HDCP, because the HDMI side is likely to require it)
CEC (Consumer Electronics Control) is for simple commands between a set of interconnected devices, e.g. allowing your TV remote to control some common functions of a set-top or DVD player, have a device turn the TV on and to it as a source, control volume, transfer a preferred device name, things like that.
CEC is mostly known under names like Anynet+ (Samsung), 1-Touch Play (Roku), and various names involving 'Link' (lots of brands).
Electrically it is a one-wire bidirectional serial bus, separate from HDMI communication so that everything but this can sleep, and is very slow (~400bit/s) because it doesn't need to be faster.
Specs say 2 or 3 meter max. This is a cautious figure and decent cable quality may go a little longer, yet don't count on more than 10-20m, and usually only for lower(-data-rate) resolutions.
Active cables could go up to 15-30m at somewhat higher rates/resolutions and a more standard-compliant way. These must be connected in the right direction (passive cables don't care).
If you want more than that, you probably want fiber DP instead of copper (at high enough rates and distances, the issue is capacitance and sort of unavoidable).
A Dual-mode DisplayPort output (a.k.a. DP++) supports the use of an adapter to single-link DVI or HDMI. (a passive adapter in that the output itself already speaks the right thing, the adapter only changes voltages)
Without this, only an active adapter (something that does a conversion between different video formats inside it) would work.
Other conversion formats (e.g. to VGA) always require this.
A single lane (differential pair) in a DP cable can be run at one of four speeds,
- 1.6GBit/s raw, ~1.3GBit/s data in RBR (reduced bit rate)
- 2.7GBit/s raw, ~2.1GBit/s data in HBR mode
- 5.4GBit/s raw, ~4.3GBit/s data in HBR2 mode (introduced in DPv1.2)
- 8.1GBit/s raw, ~6.5Gbit/s data in HBR3 mode (introduced in DPv1.3)
Cables made for higher speeds will often be 4-pair, which means:
- 4-pair HBR is ~8 Gbit/s (~10Gbit/s raw minus 20% coding overhead)
- 4-pair HBR2 is ~17 Gbit/s (~21Gbit/s raw minus 20% coding overhead)
- 4-pair HBR3 is ~25 Gbit/s (~32Gbit/s raw minus 20% coding overhead)
Your average monitor will just work - e.g. making 1920×1080 not work on a short cable would be very hard.
You would only care about these numbers if you use a combination of 4K, deep color, 120fps, and 3D, e.g.
- 3840×2160@120fps requires HBR2,
- 5120x2880@60Hz require HBR3
- multiple displays on a single port can be done
Seen used on laptops in general, and Apples in general, for monitors
Also used on Apples for Thunderbolt (1 and 2)
|This article/section is a stub — probably a pile of half-sorted notes, is not well-checked so may have incorrect bits. (Feel free to ignore, or tell me)|
Gigabit Video Interface (GVIF), carried by a single twisted pair of wires, also allowing a data channel.
Used mostly in a few automotive uses, and then largely video-only. Up to 10 meters, up to ~2GBit.
(Not to be confused with GSIF, GigaSampler InterFace)
SDI (Serial Digital Interface) is an uncompressed digital video (and audio) signal, originating around 1989 and to this day mostly seen in professional use.
Electronically: coax with BNC connectors, 75 Ohm characteristic impedance (same cabling as analog video setups, which helped upgrades, but also some confusion), 800 mV peak to peak (but receiver can deal with lower, meaning you could have maybe 300m runs of ~270 Mbit (SD-)SDI without repeaters - though that's pushing it in ways you often don't want to(verify)).
Speed variants over time:
SD-SDI: ~170..360 Mbit, allows 480i, 576i
ED-SDI: ~500 Mbit, allows 480p, 576p
HD-SDI: ~1.5GBit, allows 720p, 1080i (common for a long time?)
Dual link HD-SDI (2002): ~3GBit, allows 1080p60
3G-SDI (2006): ~3 GBit, allows allows 1080p60 (and can be easier than dual-link HD-SDI)
Network Device Interface (NDI) is a protocol that amounts to video over IP (and using mDNS for discovery).
It's not a connector, but it's recommended to run over ethernet (gigabit, for bandwidth reasons) so NDI devices often have 8P8C connectors. (You could run it over wifi, but due to the required bandwidth, the trouble is rarely worth it)
It aims at being fairly low latency, and the classical ('Full Bandwidth') NDI codec is lowish compression to get that low latency.
NDI HX uses H.264, HX2 uses H.265, both with higher latencies.
Things that speak NDI includes hardware devices (cameras, monitors), and varied PC software.
See also Local_and_network_media_routing_notes#NDI for a few more implementation details.
While TOSLINK specifies a few plugs, it is mostly associated with the optical EIAJ/JEITA RC-5720 plug, a.k.a. JIS F05 and CP-1201 - optical, mating with a square-ish shape.
Note that the exact same S/PDIF signal can also be carried over copper, then often connected via RCA or BNC, which involves fewer components and is really no more sensitive to EM noise - and avoids any conductor so cannot introduce ground loop issues.
You could argue lasers and fibers are cool, but really it's just a LED (because cheap and short-range), and something more akin to fishing wire (because more robust). That said, it was ahead of its time, and still not really replaced by another well known standard.
Mini-TOSLINK looks like a stereo jack (3.5mm TRS style) but carries the light to its tip.
This allows laptops (and other size-restrained devices) to have one small socket that provides both an analog stereo 3.5mm output, and digital audio output, in one.
There are physical adapters from TOSLINK to mini-TOSLINK.
AMP/Molex power and Berg power connectors
Molex in general is a company that makes many types of plugs.
This one has confusing history. As far as I can tell right now:
There was a Molex connector (early 60s?) that was close to the plug we later knew in PCs (the right one on the image with blue background), but incompatible.
AMP in 1963 introduced Mate-n-Lok, though its use in PCs only picked up since the late seventies(verify).
...which became used in PCs and common enough that in 1983, Molex brought out Molex 8981 which was fully compatible (basically the same) with AMP Mate-n-Lok. (Well, the 4-position Mate-n-Lok; Mate-n-Lok is actually a large family though I'm not sure it was back then(verify)).
As such, the thing we called Molex around computers for the next couple of decades (seen on larger floppy drives, on PATA HDD and CD/DVD drive connections) is either AMP Mate-n-Lok or Molex 8981. Calling it AMP Mate-n-Lok is slightly more accurate in that it doesn't ignore the decade of use that established the connector, calling Molex is much better understood, and practically there is no difference.
The plug has, in most uses, now been displaced, mostly by SATA power plugs.
(also, AMP is now called TE, but the connectors are still called AMP for findability)
The Berg plug (apparently named after its designer) was mainly used on 3.5 inch floppy drives.
While sometimes called 4-pin mini-Molex, this one is also an AMP plug, specifically AMP 171822-4 for the cable socket, AMP 171826-4 for the right Angle PCB header.
These plugs are becoming as rare as floppy drives themselves.
PCIe, EPS, etc.
The 'PCIe' naming seems to come from the fact that PCIe video card power draw is high enough that it is not sensible to get it through mainboard traces / the PCIe bus, so we decided to get it through a plug like this instead.(verify)
PCIe 6-pin (mostly seen on GPUs)
- officially: two pairs of +12V and Gnd (the last pair is specced as NC)
- unofficially often three pairs of +12V and Gnd (most such cables and PSUs allow real current draw on the third)
PCIe 8-pin - an expansion of the 6-pin (mostly seen on GPUs)
- Three pairs of +12V and Gnd
- with the pin that the 6-pin variant listed as NC now guaranteed to be a +12V
- A plug may separate the 6+2, to be compatible with both 6-pin and 8-pin variants
- the extra 2 add a Gnd and Sense
There seems to now also be a 12-Pin variant for nVidia RTX 3xxx series, apparently for space reasons, in that you can use an adapter from two 6-pins.
4-pin ATX 12V (mostly seen on motherboards)
- Two pairs of +12V and Gnd
- used for power more directly to the CPU, has been around since roughly the pentium 4
8-pin ATX 12V
- Doesn't exist and, assuming you said it because motherboard, will probably mean you're looking at 8-pin EPS12V (verify)
EPS 12V  (mostly seen on server motherboards)
- Mostly seen on server boards (and some higher-power consumer boards), meant for more current to the CPU.
- It is not ATX standard - but is effectively a derivative of it, defined by SSI
- The 8-pin EPS connector is four pairs of +12V and Gnd
- physically incompatible with PCIe 8-pin
- the 4-pin EPS connector is two pairs of +12V and Gnd(verify)
- this plug seems less common than the 8-pin(verify) (probably because 4-pin ATX 12V will do)
4+4 EPS/ATX (on power supplies)
- Refers to plug only: splittable, so that a PSU needs fewer wires and plastic to accomodate both 4-pin ATX and 8-pin EPS motherboards sockets
- That split cheats a little, but it is hard to plug incorrectly unless you get particularly creative with adapters or hammers.
- In practice, a lot of consumer power supplies just give you both a 4-pin ATX and 8-pin EPS12V, which is less confusing
PC fans are often connected with a three-pin connector (polarized variant from the Molex KK family) which supplies 12V, ground, and a sensor wire that the computer can use to count revolutions.
There were a few not-so-standard variation, such as Dell's.
You now commonly see Intel's variation, with a fourth pin to the side.
- 1 - Ground (black)
- 2 - 12V (often red)
- 3 - speed sense (often yellow)
- 4 - PWM signal - seems to often be a voltage signal that the fan uses via a transistor(verify)
6-pin (seen in servers) add:
- 5 - fan presence (lets the computer do a simpler test to see there is one connected)
- 6 - fan fault led (for visual feedback which one is broken, useful in datacenters because of cramped hardware layouts and loud environment)
As the larger sockets are physically an extension on the simper ones, this is often fairly compatible -- as long as you know which one is pin 1, which bits of keying plastic usually help with.
- 3-pin fan on 4-pin header is fine, will run at full speed - because they don't even know about the PWM pin
- most 4-pin fans are designed to work fine on a 3-pin header
You can undervolt a fan with a ghetto-ish fix: splice a fan between the +12V and +5V (e.g. from a molex plug) giving 7V.
However, not all fans spin up reliably at voltages like 7V, so check that it does or you'll have no cooling at all. This is is also why using a potentiometer for speed control is less predictable than it seems.
Using PWM is the preferred method of speed control over lowering voltage e.g. with a potentiometer, because PWM will typically work down to lower speeds than undervolting (for an combination of reasons that is a little complex).
On the 3-pin variant, motherboards officially just put 12V on the power pin. Some motherboards would instead just PWM the 12V line, which works even on 3-pin fans, but has some footnotes.
This is what 4-pin fan connectors instead adding a separate pin with PWM signal (the fan has a transistor that combines it with the 12V line), which is a more standard way of doing PWM.
If you have a 3-pin fan and a 4-pin fan socket, a little soldering you can make a 3-pin fan PWM capable (transistor and resistor, optionally a diode), but 4-pin fans basically cost the same, so this is generally not worth doing.
Note that there are little speed control boxes you plug between motherboard and fan. Which are often but not always PWM based.
IDE, EIDE, PATA
IDE (Integrated Drive Electronics) a hardware bus primarily a ssociated with ATA and its protocol.
IDE can however also refer to some pre-ATA and other not-ATA things.
Once ATA was standard, IDE and ATA were used more or less interchangeably.
Once SATA existed, a distinction between SATA and IDE(-as-in-parallel) became convenient, so both IDE and ATA became a bit vague, and we started using SATA and the retronym PATA (Parallel ATA) became a clearer way to refer to this 40-pin connector.
- If there are two devices on a single PATA cable, one is called master and the other the slave (jumpered that way, or sometimes implied via its position on the cable)
- These names are not official. They also do not refer to interaction between the drives at all - both drives operate independently, using their own controllers and both only talking to the host. It was just a way for the host to distinguish between two on the same cable.
- There was also EIDE, Enhanced IDE, referring more vaguely to early adoption of some features of a then-future ATA standards. The term was also abused by marketing at that time
'ATA with Packet Interface Extension' is actually about protocol, not plug - it can be carried over PATA or SATA.
ATAPI is an extension based on SCSI protocol features, that made it more useful for certain (additional) drive types, such as CD, DVD, and tape drives.
In this context, ARMD ('ATAPI Removable Media Device') was mainly used to refer to ATAPI drives other than CD/DVD drives. Often meaning tape drives.
Early CD drives: Panasonic, Sony, and Mitsumi
Before ATAPI caught on as the standard for CD drives, and multiple ATA controllers became common on motherboards, these three companies created proprietary interfaces (sometimes called AT-BUS and other things) to connect CD drives of their own styles.
Certain expansion cards, e.g. the Sound Blaster 16, exposed these connectors as a simple way to connect these pre-ATAPI drives without needing another specific interface card. (TODO: look up the details)
Sony used a 34-pin IDC/ribbon connector.
Panasonic and Mitsumi used 40-pin IDC/ribbon connectors (that were potentially confusable with PATA connectors, particularly when used for later CD drives that use ATAPI).
Side note on ATA
ATA refers to "Advanced Technology Attachment", effectively a set of standards that encompasses Parallel ATA, ATAPI, Serial ATA (SATA), and more.
ATA versions and introduced features:
- pre-ATA standards had varied limits, particularly in the DOS era
- ATA-1 (1994) - PIO 1 and 2, 28-bit LBA for sizes up to 137GB
- ATA-2 (1996) - PIO 3 and 4, DMA 1 and 2 (the terms 'EIDE' and 'Fast-ATA' appeard around this time)
- ATA-3 (1997) - SMART, connector for 2.5" drives
- ATA-4 (1998) - UDMA 0, 1, 2 ('UDMA 33')
- ATA-5 (2000) - UDMA 3, 4 ('UDMA/66')
- ATA-6 (2002) - UDMA 5 ('UDMA/100'), 48-bit LBA for sizes up to 144 PB
- ATA-7 (2005) - UDMA 6 ('UDMA/133'), SATA 1.0 ('SATA/150')
- ATA-8 (in progress; there is a working draft you can get)
SATA has its own versioning: 
- SATA 1.0
- SATA 2.0 (2004)
- SATA 2.5 (2005)
- SATA 2.6 (2007)
- SATA 3.0 (2009)
- SATA 3.1 (2011)
- SATA 3.2 (2013)
- SATA 3.3 (2016)
- SATA 3.4 (2018)
SATA: Serial ATA, is part of ATA-6 and later. Has basically replaced PATA.
There are variants, but most of us care about the 7-pin data cable (and the 15-pin power cable).
The data socket can be as minimal as just the plastic to hold the contacts, but most sockets are a variation with a plastic shroud (see first image), making it harder to break. This will also accept the clip present on some cables.
Basic SATA's basic power connector has so many pins for scalability reasons - it provides three voltages (3.3V, 5V, 12V), with three pins each to be able to meet requirements of power hungry drives (while not exceepding 1.5A per wire), plus one signalling cable.
This cabling is often not necessary, and there are slimline and micro versions of the power connector, which use simpler wiring, and are good enough for the drives they're meant for.
For external use there is eSATA, which is pin-compatible and functionally identical. The main differences lie in electronic, cable length, and physical specs, and the connector and socket are different enough so that you can't plug SATA cables meant for internal use onto external ports. (There are dumb adapters, but you should be aware of what you're defeating, and will also have trouble around SATA ports that disable themselves at boot if there's no drive on there)
There is also eSATAp (often marked eSATA+), which is a connector that adds power, and the ability to plug in USB into this same socket. Keep in mind that this may be either USB2 or USB3 (you can usually tell by the color).
eSATAp is a variant of eSATA that carries also carries power -- and also USB.
Only SATA's 5V line is guaranteed on this plug, the 12V line is optional. Desktop computers typically provide 12V, while laptops often don't(verify).
This means eSATAp sockets can typically power 2.5" drives (which only need +5V), but only the desktop variants can power external 3.5" drives (which also need 12V).
eSATApd unofficially refers to having both voltages.
SAS and SATA are quite similar, and in many areas compatible.
This is by design. You could see
- SAS (Serial Attached SCSI) as the fancier variant of SATA that targets the business market, adding more options and features, more practical variations in controllers, cables with more channels to attach more drives (and have cable failover), options to connect externally as well (e.g. drive bays), and other such options.
- SATA as the simpler, one-drive-at-a-time consumer variant
- (well, with footnotes. There were things like SATA port multipliers but controller support varied)
- that is simpler to use cheaper to make
The protocol is also very similar, though SATA's requires command is a subset of SAS's(verify)), both are switched, point-to-point, serial, full-duplex, can transfer approx. 300MByte/sec per port (current typical; both have variations and plans), and can be hot-plugged (electrically, anyway. Your BIOS and OS may have their ideas about enabling and resetting ports).
The SAS drive interface is SFF-8482.
It looks a lot like SATA, and can indeed connect SATA as well as SAS drives.
The SAS and SATA drive connections are closely related, and in fact pin-compatible. You can physically plug SATA drives onto SAS controllers, the SAS drive connector (SFF-8482) allows it, and SAS can tunnel SATA. This means server backplanes are easily designed to take SAS and SATA alongside each other.
SATA cannot tunnel SAS, and for this reason you cannot use SATA cabling on a SAS drive. Physically because of the extra plastic, but even if you find a physical adapter (they exist, though I'm not 100% on why), it probably won't work(verify).
- Beyond single drives
Because of varied use cases, there are a whole bunch of internal connectors standardized by SAS, e.g. to carry a handful of channels between drive bay backplane and controller.
Many of them are used more in servers, but some of them are obvious choices in handful-of-drives consumer RAID hardware as well.
See e.g. 
Uses the more general PCI Express Mini Card ('mPCIe') connector as a small drive connector (data+power).
...which caused some confusion, because some sockets were mPCIe, and some mSATA-only (verify)
Was seen in smaller laptops and such for storage, where it is now mostly replaced by M.2
A form factor spec for expansion cards in general, standardized around 2013 (then known as NGFF (Next Generation Form Factor), before it was renamed to M.2)
Can carry include SATA 3, NVMe, USB 3, and (multiple lanes of) PCIe 3.
Does not support/guarantee hot-swap. But there are specific cases where this works.
Consumers mainly see this used for storage, in which case you can consider it a replacement of PCI Express Mini Card connector (and its use for mSATA).
If your PC doesn't have M.2 on-board, there are PCIe plug-in cards with M.2 sockets. If your laptop doesn't, you probably can't use it.
Also keep in mind that it's new enough that not all current systems can boot off M.2 - in which case you can't (easily) use it for your system drive. So you want to check that. And there's no upgrade path other than upgrading at least half your computer's hardware.
Widths include 12mm, 16mm, 22mm (which seems most common) and 30 mm
Lengths include 16, 26, 30, 38, 42, 60, 80 and 110 mm
The basic shorthand is those two appended, e.g. 2280 for 22mm by 80mm
A shorthand with more dashes, like WWLL-HH-K-K or WWLL-HH-K, encodes more details (like single/double-sided, maximum thickness of components, and more)
The notchings (specific gaps in the socket/connectors) are intended to not allow inserting into certainly-incompatible hosts. There are about a dozen of them, but half of them are currently reserved.
If you can plug it in it should not damage anything, but it is also not guarantee it will function as expected.
The notchings seem to mostly be for things that almost certainly wouldn't work - and are loosely correlated with use. For example:
- B and M are wider use (including PCIe lanes), in practice frequently SSD (SATA and/or NVMe)
- B has one side has short piece with 6 pins
- M has one side has short piece with 5 pins
- BM has both of those notches
- For WiFi you'll see A and E (verify)
For more practical reasons, notchings are also somewhat correlated to sizes, e.g.
- A and E are rarely longer than 30,
- while B and M may use up to the full length, and rarely as short as 30.
M.2's relation to NVMe
NVMe is storage over PCIe communication.
Which makes NVMe an alternative protocol to SATA when connecting SSD drives.
Pluggable storage that speaks NVMe currently correlates strongly to M.2 connectors - so M.2 and NVMe are often seen as roughly the same thing, and used as near-synonyms by some.
Which is sort of wrong - M.2 can carry SATA, or NVMe, or both. And which ones a devices speaks is further up to that device.
When M.2 carries NVMe, it allows higher bandwidth (which most SSDs don't need yet), and also : has queues that makes it easier to use the parallelism of fancier SSD designs (e.g. allowing parallel reads), which makes it potentially faster and lower latency than SATA SSD.
How much faster is frequently overstated, at least for most current devices. It's much more a "potentially better", and headroom to be a good interface for a good number of years, much less a guaranteed to be better right now.
More to the point, even if it would for best-case benchmarks, in practice it depends a lot more on the actual workload than the marketing graphs would like you to realize (which is the point of these graphs, of course) because those were made on very specific workloads.
Rather than five times faster everything, you may find increase on most everyday use is more like a few percent to a few dozen percent. Cases that may see a little more may include some servers, some video editing, some games see a modest difference (in loading time, and then only to the degree it is not bound by something else).
So whether the price/performance is worth it depends the same way.
That said, NVMe it is preferable for SSD so is likely the preferred interface for SSD in the future(verify).
Apple's SSD connectors
Apple has used various different connectors over time, none of them M.2 (fair in part in that half of them predate M.2).
- 'first generation', a 6+12 pin (around 2010) (carries mSATA III(verify))
- 'second generation', a 7+17 pin (around 2012) (carries mSATA III(verify))
- 'third generation', a 12+16 pin (around 2014) (carries PCIe (verify))
- with a later variation that uses a 40 pin mezzanine adapter (verify)
- 'fourth generation', (~2015) same connector, but higher speed (verify)
- 'fifth generation', (~2016) same connector, but higher speed and speaks NVMe (verify)
There are often physical adapters from M.2 (the protocols these things speak don't seem to differ), letting you use more generic SSDs, but you must do the research both on compatibility and whether it will fit.
Roughly from most to least common (well, a guess at that):
- USB A: The plug/socket seen on the computer side and USB hubs (and sometimes elsewhere, e.g. on printers for direct camera connection)
- USB B: Used on the device side for bulkier devices, such as scanners and printers, where there are no space limitations, and sturdiness is handy
- USB-C: Invertible. Seen on smartphone, some apple products. (released ~2014.
- Developed parallel to USB3, and as of this writing the two don't support all the same features (verify)
- USB micro-B plugs and sockets, meant for use in thinner devices. example: smartphones data/charge cables.
- USB mini-B: Used by various smaller devices, such as cameras, MP3 players, some phones
- USB3 A: Plug adds the extra lines for USB3, but remains the same size. Socket can take earlier (USB1, USB2) USB A.
- USB3 B: Plug adds the extra lines for USB3, and is bigger. Socket can take earlier USB B.(verify)
- USB3 micro-B - basically USB2 alongside USB3(verify), separated with a notch. Seen e.g. on 2.5" external hard drives, USB3 hubs.
- USB3 Micro-A (looks like USB3 micro-B but squarer) exists only as a plug, and seems rare
- USB3 Micro-AB (looks like USB3 micro-B but squarer) refers to a socket that takes USB3 Micro-A and USB3 Micro-B, also seems fairly rare
- USB mini-AB socket (socket only), relatively rare, can accept both Mini-A and Mini-B plugs.
- USB micro-AB socket (socket only) that can accept both Micro-A and Micro-B. Defined by USB On The Go (OTG) (2001 standard)
- USB micro-A plugs and sockets, meant for use in thinner devices
- USB mini-A: was never seen that much, perhaps because it is confusable with mini-B.
- There are many non-standard plugs that are relatively rare.
- Say, I've seen cameras use approximately-8-pin sockets with different cables that connect either USB, or things like audio+video. This plug is sometimes confusingly called B(-type).
- USB 2 has four pins:
- power lines are 5V and ground
- data is 3.3V differential
- the fifth pin on micro plugs is OTG ID, and is either tied to ground (marking that side as host side) or floating (marking it as device side) (verify)
- USB3 
- leaves all those USB2 in there
- adds five more:
- two differential pairs
- and a ground
- USB version 3 are often indicated with either blue plastic, or SS (for Super Speed, the mode that USB3 adds)
- micro plugs/sockets are often not blue, possibly because it would be hard to see anyway(verify)), and because they're less ambiguous that PC-side A sockets
- The USB1/2 mini connectors are approximately 3mm by 7mm, the micro versions are mostly just thinner, making them useful on very slim devices like smartphones.
8P8C / Ethernet cable
For the series of connectors, see #Modular_connector_.28and_Registered_Jack.29.3B_.3FP.3FC
For the use of 8P8C in ethernet, see 8P8C / RJ45
Firewire (IEEE 1394)
IEEE 1394 is better known as FireWire (Apple), and sometimes i.LINK (Sony), and Lynx (Texas Instruments).
It was meant as a successor to parallel SCSI, and is also commonly used for some digital cameras, and for high-end audio and video devices. Was a potential competitor to USB in many areas, but while USB is somewhat slower (depending on which variant of FireWire and USB), USB is more popular for many things.
- smaller, e.g. used on more portable devices like cameras. Data-compatible with the 6-lead connector, but doesn't provide power. Initially developed by Sony, later more widely adopted(verify)
- two twisted pairs of data
- 6-lead ('alpha')
- two twisted pairs of data, power
- 9-lead ('beta')
- two twisted pairs of data, power, shield (verify)
- 8P8C connector (used in 1394c)
- IEEE 1394, specifically IEEE 1394-1995
- IEEE 1394a, specifically IEEE 1394a-2000, also known as FireWire 400
- Uses the 4-lead and 6-lead ('alpha') connectors
- IEEE 1394b, specifically IEEE 1394b-2002, also known as FireWire 800 (Apple's name)
- adds the 9-lead ('beta') connector
- IEEE 1394c, specifically IEEE 1394c-2006, also known as FireWire S800T
- adds the 8P8C connector
Fast peripheral interconnect by Intel and Apple. (Developed by Intel under the name Light Peak, since renamed)
Thunderbolt 1 reuses the Mini DisplayPort connector; thunderbolt capability is indicated by a lightning symbol.
- Can carry DisplayPort, one or more PCI Express lanes, and up to 10W of power.
- Copper cables carry two 10GBbps (1.2GByte/s) lanes, of which any device can use only one (seems a fair-sharing thing)
- Assume ~3 meter max over copper(verify)
- Can daisy-chain a few devices (though individual devices have to have the plugs for it, and allow it)(verify).
- Much like 1. Largest difference seems to be that a device can use both channels(verify)
Thunderbolt 3 uses USB-C connectors. Plugs and sockets should bear the thunderbolt logo to lessen confusion.
- Speaks more protocols (DisplayPort, PCIe, USB 3, ...)
- Allows adapters to the previous MiniDP plug
- Not guaranteed to carry 10W as before (though USB could choose to do more than that) (verify)
- Assume it can do 20Gbps as before. Short or active cables could do 40Gbps(verify)
On Thunderbolt 3, USB3, and USB-C
- ...or some combination.
It is context-dependent which protocols the endpoints care to speak.
This is both nice and potentially confusing. Yes, it reduces the amount of connectors you need and makes USB more universal.
But also, there will be various lots of incompatibilities and confusion that won't be easy to explain to everyone.
Say, Thunderbolt 3 chose USB-C plugs/cable (previous versions used mini-DisplayPort), so TB3 can in many contexts be seen as an extension of USB3. But a Thunderbolt3 device will do nothing on a USB3-only host. Probably.
USB-C cables are created roughly equally, at least in theory.
- not all cables support the same speed
- it may be capable of sustaining 40Gbit, 20Gbit, 10Gbit, 5GBit, or even just 480Mbit(verify)
- and which of the standards (TB3, DP, USB3, USB2) and which of their modes will work may vary
- not all cables support charging (verify)
- and if they pretend to do so, but are out-of-spec knockoff cables, this is riskier these days, because there is more current involved than in earlier USB
Uses the 6-pin mini-DIN connector. For keyboards, this replaced the larger DIN plug used on AT style computers before PS/2. For mice, this became an alternative to serial port mice, though USB is now also quite common for keyboards and mice.
D-subminiature have a keystone-shaped shell for seating and earthing, and typically fastened with screws.
Most have two rows of pins, some three.
Spacing of pins within a row is 2.76mm, rows are 2.84mm apart. (2.3 mm and 2.0mm in HD variants(verify))
- The second letter indicates the shell size (A through E),
- followed by the number of pins present,
- and sometimes the M or F for male/female (originally P and S for plug and socket)
Given the shell size and pin spacing, there is a typical amount of pins for each size of shell when there are 2 rows: 15 for A, 25 for B, 37 for C, 50 for D, 9 for E.
There are however exceptions, like the three-row variants (e.g. DA-26, DD-50, DE-15), and sometimes other things in there (e.g. DB13W3).
Some common examples:
- DE-9: often a serial port (RS232) interface
- DB-25: Parallel ports (also once for serial ports, with inverted gender), sometimes (older) SCSI
- DE-15: VGA monitor connectors. (Uses three rows of pins. Also technically called HD-15, where HD stands for the High Density of the pins compared to other D-Sub plugs)
- DA-15: On older PC sound cards, this is a game port, originally for joysticks, later more for MIDI cables
Some people abuse specific letter codes thinking that they referred to the D-sub plugs in general, and started patterns of misleading use for those that do know what they mean, e.g. DB15 to refer to DE15 (VGA) or DA15 (gameport).
There are smaller variants called Micro-D and Nano-D, mostly seen in military and space use.
- http://en.wikipedia.org/wiki/DB13W3 ('Sun video', or SGI/DCC)
The plug is called an insulation-displacement connector, IDC (see also DIN 41651).
In computer (building) circles it is common to refer to IDC on ribbon cables as just ribbon cables, not naming the plug.
The IDC pitch (hole spacing) is often 2.54mm (0.1 inch), though there are variations.
For example, parallel ATA connectors for laptop disks often had 2.0mm pitch.
Common IDC plug variations in computers:
- 40-pin (2x20, 2.54mm pitch - 3.5" hard drive connectors (parallel ATA)
- 44-pin (2x22), 2.0mm pitch - 2.5" notebook hard drive connectors (parallel ATA)
- 34-pin (2x17), 2.54mm pitch - floppy connectors (controller side, and drive side for 3.5" floppy drives)
- also old Sony CDROM drives, see above
- Some motherboard-connected ports not directly on motherboard, e.g. an extra serial port, audio connectors (varying pin details), extra USB ports (varying pin details), and more
- used internally in a lot of places, which may be more case-specific and less standard than various of the above.
The shell's shape is like that in D-sub, but the connectors are strips, not pins, and fastening is clips, not screws.
Perhaps best known for use in
- 36-pin: IEEE 1284 printer cables, specifically a male DB25 plug to male 36-pin Centronics plug (this use is mostly outdated)
- This variant and use is also known as the Centronics connector, as they introduced it. People will call more variants Centronics because of this association.
- 50-pin: SCSI-1 (also mostly outdated)
Also used in
- a telco connector 
It is apparently also known under names like Contronics, telco, 25-pair, miniature delta ribbon, mini D ribbon, delta ribbon, MDR, Amphenol, and CHAMP.
Now rarely seen.
Mini-centronics looks like micro ribbon (a.k.a. centronics), but thinner.
(Used to be) Most likely recongized as 'something to do with SCSI', though it also sees other uses.
- 36-pin: printer cable (as a compact version of the basic Centronics 36-pin)
- 50-pin: SCSI-2, SCSI-5
SD and MMC
Physical size: There's mainly
- SD (24x32x2.1mm) (MMC was apparerently a little thinner?)
- microSD (11x15x1.0mm)
- previously called TransFlash (abbreviated TF and T-Flash), and some parts of the world still prefer that name
- There's also MiniSD, which never really took off
The variants are pin-compatible (some footnotes on the faster ones with extra pins), so adapters to larger sizes exist, and the choice of which you want relates more to the device. For example, cameras and laptops and generic card readers often prefer SD, which is a little sturdier and less fiddly to move around, smartphones use microSD because of the smaller size and it being more or less permanently in there anyway.
When released around 2000, they were tens of megabytes large (apparently allowed for up to 2GB(verify))
SDHC (~2007) allowed up to 32GB
SDXC (2009 and later) allowed sizes up to 2TB, and optionally allowed designs that go at higher speeds.
Basic speed is 12MB/s, or 25MB/s when clocked at double rate
UHS variants go up to 100MB/s or a few multiples of that, depending on the variant, and on card and reader support.
- readers that are connected via USB2 will implicitly be limited to ~40MB/s in theory but often ~25MB/s in practice (which may be less than the controller's and/or SD card's capabilities).
- there are a few footnotes to compatibility, e.g. that the newest generation are not guaranteed to work in the oldest readers
- More technical details at: On_computer_memory#Secure_Digital_.28SD.2C_miniSD.2C_microSD.29.2C_and_MMC_details
In today's context, MultiMediaCard (MMC) (since roughly 1997) was the predecessor for SD cards (since 1999).
Because SD builds on MMC both physically and in terms of protocol, many SD controllers will still accept MMC cards.
Variants of MMC (some of them specialized or local) have come out until recently, but MMC is generally much less common than SD cards.
Like SD, MMC had some size variants (see e.g. MMCplus, MMCmicro). More than the later SD, in part because it was an open standard so let companies roll their own.
Basically a PATA bus, and talking ATA.
Often contained flash (which was initially fairly small), though initially also for very small hard drives (microdrives).
It offered good features early on (compared e.g. to SmartMedia), but was later displaced by smaller and faster formats - though the sturdiness let it hold on in certain uses, e.g. photography where huge storage size is less important.
Physical size: 36m high, 43mm wide
- Type I is 3.3mm thick
- type II is 5mm thick
Type II was mostly used by microdrives, also because II is allowed to draw more current than I. As microdrives were fairly quickly displaced by flash-based storage, most CF cards are Type I, and not all devices do not fit Type II cards(verify).
Initially, sizes were dozens to hundreds of MByts, because when it was design (mid-nineties) a GByte was more storage than a lot of PCs had. In the 2000s they grew to dozens of GBytes.
Recent CF5.0 allows much larger, though in a lot of uses a hundred GByte or so is more than you need, and larger may be better served by a more modern, faster format.
Because it's really just ATA, the maximum speed varies with ATA version.
Original specs were limited to PIO modes, which top out around 25MB/s.
Later UDMA modes supported up to 166MB/s, and some CF is actually that fast, which is still on par with modern SD cards.
Yet regular CF didn't go much faster than 20MB/s or 30MB/s from decent cards(verify), and maybe single digits from cheap ones (note: like cheap SD today). (probably in part because various ways of reading out didn't go much faster anyway - card readers were often USB2 at the time, which doesn't often go faster than 30MB/s, and some IDE to CF adapters lacked the faster modes(verify). Also, older devices that used CF might not support newer (UDMA) modes without a firmware update, or at all.)
The x speed rating is multiples of 150KB/s (like in CDs), so e.g.
- 133x is approx 20 MB/s
- 1066x is approx 160MB/s.
Note that the listed speed is usually the read speed, not the write speed.
Memory Stick (Duo, Pro, Micro (M2), etc.)
The three sizes are electronically largely identical, and adapters from M2 to Duo-size and standard-size exist.
Seen on mobile phones, cameras, The PlayStation Portable, etc. Competed mainly with SD and CF at the time.
- original: 128MB
- PRO: 32GB (probably the most common)
- XC: 2TB
There are three physical sizes (which you could call Standard, Duo, and Micro):
- that of the Memory Stick Standard, PRO (longer and thicker than the Duo)
- that of the Memory Stick Duo, PRO Duo, PRO-HG Duo (shorter and thinner than the standard)
- that of the Memory Stick Micro (M2)
If you haven't seen them before
- the Standard and Duo's angled corners make them somewhat confusable with SD.
- The size of the micro (M2) makes it somewhat confusable with the microSD.
A few types, sizes up to 512MB and 2GB varying with them.
Apparently quite similar to SmartMedia
- quite thin (0.76mm), feels fragile
- capacity limited to 128MB (...so not seen much anymore)
Plugs desiged (mostly in terms of shielding and impedance) to carry radio frequencies, associated with carrying video, data, and more.
Belling-Lee (IEC 169-2)
Used for TV (and radio) connectors in some European countries, and Australia.
Diameter is 9.52mm.
Some people seem to call this a PAL connector, probably through association with the countries this is seen in.
Some call it a coax plug, which is even vaguer.
Note that on houses with more serious installations, it's not unusual to see these only in the eventual wall-plug and the cable that goes to the TV, and something like F collectors on cabling (and signal boosters) before that. This because the Belling-Lee plugs are not ideal for VHF and UHF frequencies (but fine for MW and Shortwave) so you really don't want them more than once in your chain if you can help it.
F Connector (IEC 169-24)
Often used for cable television / cable modems, satellite television, and (American) TV aerial connections.
A little less lossy for VHF and UHF than Belling-Lee is, so is seen in more places in infrastructure(verify).
BNC, Bayonet Neill-Concelman (apparently also sometimes Baby Neill-Concelman connector, Baby N connector, British naval connector, bayonet nut connector) was once common for networking. Still used for some antennae, video (then often composite video), occasionally audio and other things because it's coax (so shielded).
TNC, Threaded Neill-Concelman, is a variation on BNC with a screw thread system (BNC uses bayonet).
Reverse TNC is reverse in that the inward/outward threading is switched between male and female plugs. This is seen e.g. in older/larger WiFi antennas, an area where the smaller R-SMA is also regularly seen for the smaller ones(verify).
The Type C Connector looks like BNC, but is bigger.
(BNC was developed as a smaller version of this )
SMA and reverse SMA
Diameter: ~6mm for the thread/female, ~8mm for the male/outside
SMA is short for for SubMiniature version A. There are also SMB and SMC connectors.
A variation on SMA called RP-SMA ('reverse polarity') is used in WiFi antenna connectors (the larger R-TNC also sees use there, mostly on older APs).
Diameter: ~4mm for the thread/female
U.FL / MHF / I-PEX / IPAX / IPX / AMC / UMCC
These various names all refer to tiny connectors for high-frequency RF signals (up to approx 6GHz), and seem mostly interchangeable(verify). Seen in various mobile and wireless applications.
There are adapters to things like (RP-)SMA sold for applications such as WiFi, mobile modules (particularly M2M), and others.
Unsorted RF connectors
Power - device side
Low/medium voltage, device side
...e.g. adapters, battery packs, solar panels, and such.
Meaning up to a dozen volts, generally up to an amp or two.
DC connectors, EIAJ power, coaxial and more
Usually used for low-voltage power, most under 20V, and (so) typically used for DC.
Up to a few millimeters thick, often either concentric barrel-style or tip-(ring-)sleeve style.
Most are not so much standardized as they are used by convention, and consistently produced. There are enough variants htat it can can be hard to recognize even some more standard ones with certainty.
There are perhaps half a dozen common plugs/sockets, and probably at least a dozen or two more variants.
In the image on the right, from top to bottom:
- 2.5mm TS
- 3.5mm TS (confusable with audio)
- 5.0mm barrel (~6.2mm tip) (verify)
- EIAJ-01 (2.35mm barrel, 0.7mm inner diameter)
- 3.5mm barrel (1.35mm(verify) inner diameter)
- EIAJ-02 (4.0mm barrel, 1.7mm inner diameter)
- 5.5mm barrel, for 1.5mm pin
- 5.5mm barrel, for 2.5mm pin
Terms, standards, plugs:
- IEC 60130-10 (:1971) defines five/seven connectors
- Type A: 5.5 mm outer diameter, 2.1 mm inner diameter (seems the most common?)
- Type A: 5.5 mm outer diameter, 2.5 mm inner diameter
- Type B: 6.0 mm outer diameter, 2.1 mm inner diameter
- Type B: 6.0 mm outer diameter, 2.5 mm inner diameter
- Type C: 3.8 mm outer diameter, 1.4 mm inner diameter
- Type D: 6.3 mm outer diameter, 3.1 mm inner diameter
- Type E: 3.4 mm outer diameter, 1.3 mm inner diameter
- 'EIAJ connector' usually refers to one of the EIAJ RC-5320A connectors, rather than the other two:
- EIAJ RC-5320A  defines five different thicknesses of barrel pairs rated for 2A. Yellow-tipped DC connectors are likely to be one of these.
- EIAJ RC-5320A
- note that this is simplified -- these have inner and outer diameter for both plug and socket
- EIAJ RC5322
- Barrel type connectors, 6mm outer, 3.1mm inner radius. Pin is 1.0mm
- wide (6.5mm) plastic tip, apparently to avoid contact in cars and such
- EIAJ RC-5322
Telling which one you have or need is sometimes be a bit of a challenge.
Small mismatches on the slightly-smaller side tend to be okay, because these are often held by spring contacts.
For example, my big box of power supplies and wallwarts, 5.5mm-outer barrel connectors is the most common, and seemingly mostly with 2.1mm inner diameter, maybe a few 2.5mm. (I should verify this, but need a pin of known and fairly precise size).
Also, there are a lot of barrels that don't have a solid inside but two (spring?) contacts.
- So e.g. a socket made for 5.5mm outer, 2.1mm inner diameter
- will likely also accept 4mm 2.1,
- and probably 5.5mm 2.5mm.
- though a 5.5mm outer, 3.4mm inner may not make contact.
However, a socket with a 2.5mm pin won't accept a 2.1mm inner-diameter.
3-Pin and 4-Pin DC Plugs
Doesn't seem to have any singular standard, name, or pinout.
Everyday names seem to include:
- snap and lock (though not all variants lock),
- (incorrectly(verify)) power mini-DIN, power DIN - misleading as this does not mate with any mini-DIN plugs or sockets, because of the thicker pins than DIN, and often larger shell (the ones I saw were ~10mm instead of mini-DIN's 9.5mm)
Often used to deliver two different voltages, and/or more current than basic DC plugs are comfortable with.
There seem to be a bunch of these, most probably unrelated in origin, probably unified more in "seems solid, had has the two/three/four thick-enough pins I need", some of which seem to be are niche standards.
I should probably try to find more of these, but don't count on it.
Seen in cars or RC
Cigarette lighter plug
Known as cigar(ette) lighter plug, vehicle receptible, and others. Also called a 12V plug, since this is usually what is provided (some exceptions).
Note that there are actually three variations of this plug, with mildly different sizes. Since many have plugs with more than a mm of spring on the side, they tend to be more or less interchangeable, though it's not always the most comfortable fit.
Mates with an identical plug. Seen in cars, motorcycles, some batteries, some solar panels, and such.
Meant to be wired so that the exposed lead from the power source may safely touch the car chassis.
Mostly seen in RC applications
Tamiya is regularly seen in RC battery packs. Seems to refer to the plastic's plug/hole shapes (resembles a 2-pin Molex Mini-Fit Jr.) that make this a polarized connection (the square one is positive, the rounded-on-one-side one is ground).
Tamiya seems to be considered a cheapish choice that is good enough for up to a few amps. Or more, depending on the shape and material of the actual connectors(verify).
Also exists in mini variation.
The Deans Ultra is a polarized connector made to carry serious current for its size (smaller than e.g. Tamiya), largely because of the connector shape.
Flat contacts, one side with springs that push the other side for good contact area.
Rated up to 60A. (but there are some cheap imitations that you don't want to push that high - I recall some rated at 10A(verify))
There is also a smaller micro Deans, rated for a dozen amps.
Powerpole - Anderson PowerPoles (also known as sermos) are rated for ~30A. Can be crimped. Larger than other choices, which makes it easier to pull apart than some other higher-amp choices, and lasting somewhat longer.
EC3 is a polarized plastic plug (resembling Tamiya) around bullet/banana-style connectors, and rated to approx 60A. They're relatively cheap(verify), so are handy all-round plugs.
People report them being a little easier to separate than Deans. The plastic may deform when things do heat up, though.
There is a less common larger variant called EC5
Bullet connectors are a solid tube and a solid pin. They may be good for a few dozen or even a hundred amps or so.
Since they are really just two bits of metal, they're probably also the cheapest thing you could call a connector. Of course, without a plug around it (and with some cheap plastic plug designs) you expose metal in ways that easily lets you short things out.
Note that when it comes to moving a bunch of current, the fact that there are multiple differently produced things, that often won't fit each other very well, will matter.
Confusable with banana plugs. Cheap banana plugs may count on their smallish spring for contact, which means little contact area and so not be good for high currents. Better designed banana connectors may be almost equivalent to bullet plugs.
XT60 is a polarized bullet-based plug rated for ~60A, and uses plastic that deals well with temperature.
There's more variants of this, like XT30 and XT90
Kyosho is comparable to tamiya in rating and also looks similar to it (also resembles EC3 in details).
Also exists in a mini variation.
Unsorted RC-ish power connectors
Mentioned by http://www.flyrc.com/articles/connectors_1.html
- Astro Zero loss 2-pin
- Astro Zero loss 3-pin
- Sermos power poles
- Duratrax power poles
- Castle Creations 13- AND 16-gauge power poles
Mains power, device side
Refers to IEC 60320 (IEC 320 before the renumbering), the plug/socket system commonly used on devices which can use various socket-to-device wires.
C1 through C24 are defined, and the male and female versions of a type connector have different numbers. Many are polarized. For a few there are variations (e.g. C7/C8), and some are variants of other IEC plugs (e.g. C17/C18 is unearthed variant of C13/C14).
The most common are probably:
- C13/C14, commonly associated with PC power supplies, and other devices that may need its moderate current rating (over e.g. C5/C6), including some professional audio equipment.
- Rated at 10A
- Rated at 16A
- seen where you may need a bit more current than C13/C14 gives
- e.g. computer racks may have C19-to-C14 or C19-to-C20 Power Distribution Units
- C5/C6, regularly seen in laptop power supplies and other PC-related power supplies.
- rated for 2.5A
- C7/C8 (a.k.a. 'figure eight', 'shotgun'), unpolarized, ungrounded, is seen on various lower-power devices, from radios to VCRs, some laptop power supplies, game consoles.
- rated at 2.5A
- polarized C7 won't fit into unpolarized C8, which is rarely a problem(verify)
- unpolarised C7 connectors can be inserted into polarized C8 sockets, but this can sometimes be a bad idea
- A little larger than C1/C2
- C1/C2, commonly seen on shavers.
- Rated at 0.2A
- Looks like C7/C8 but without the dents that make it figure-8
Variants with higher temperature rating include:
- rated for higher temperatures (120°C)
- very similar shape to C13/C14, but notched so that only the higher temperature cables are accepted
- e.g. used for electric kettles
- C15A/C16A, similar
- rated for higher temperatures (155°C)
- notched like C15 and blockier on the other side, to be more selective (C15 devices will accept C15A cables as well, but not the other way around)
Mains power - wire-to-wire connectors
Screw terminals terminal blocks, terminal strips and others names are used interchangably, making many somewhat ambiguous.
Not all types are rated for mains voltages, though the ones with separators often are(verify)
Often refer to a screw-and-nut through a flat strip - which are not always the easiest to use on braided wire, and you may prefer to attach forked spade lugs (or loop lugs)
Luster terminals, a.k.a. lustre terminals, which seems to come from the german Lüsterklemmen, seem mostly seen around europe.
There are a few local names, like kroonsteen (Dutch), suikertje (Flanders).
Originally porcelain and of larger and simpler design (screw clamping two wires together), intended to be heat isolation. (And you still see ceramic variants of this newer design, e.g. for use around saunas)
Spade connectors are a solid bit of metal, and the female part a good amount of area clamping down so these tend to connect very sturdily. (Some also have a clip to make it harder to slide unintentionally)
Various sizes may be rated something between 3 and 24A (order of magnitude).
The female type is frequently shrounded, for isolation.
You see spade connector bars to connect various circuits together in this style.
Related are the eye and fork variants, which are easier to screw down.
Push-in style connectors will often push a pushing into spring loaded, sharp construction that tend to dig in a little, and tend to not let you pull out solid core without a bunch of force and/or twisting.
You can often find these rated for something on the order of 24A.
Lever locks clamp a spring down on a wire (varied designs, various of which are smarter than a basic basic pressure plate).
Many are made for wires of sizes like 22AWG to 12AWG, and rated for at least 20A, e.g:
- WAGO 222 are spring-clamping connectors rated for 400V/32A (though tests have show they're electrically fine up to perhaps 100A, it's the heating you need to worry about)
- WAGO 221 is a smaller variant of the WAGO 222, rated at a very similar 450V/32A (and 600V/20A)
Details are usually listed on them.
Wire-nut, a.k.a. wing nut, twist-on, twister, twist cap connector
On circuit currents
Power - wall plugs
The types are a less formal(verify) way of indicating the common plugs to use around the world.
Some of the more common plugs are listed below (lettering system as used by some US document on worldwide power)
Some practical knowledge before traveling: https://www.electricalsafetyfirst.org.uk/guidance/advice-for-you/when-travelling/travel-adaptors/
Type A, Type B, household NEMA variants, JISC C 8303 Class II
(North America, Japan, some other places)
- NEMA 1-15 is a 2-prong non-earthed plug, a.k.a. Type A
- NEMA 5-15 is a 3-prong earthed plug, a.k.a. Type B
- NEMA mentions about two dozen other variations
- most for higher currents, which is why you don't see them in everyday life
- some polarized
- You may have seen NEMA 5-20
- ...where the 5-20 plug has one blade horizontal...
- ...and the 5-20 socket includes a T-shape to accept both the 5-20 plug and 5-15 / 1-15 plugs, mostly in commercial settings where single devices may be designed to draw more than 15A
- There are more high-current NEMA plugs, about a dozen in total - but most of them are 20, 30, and 50A which you will only need or see in commercial and industrial settings
The US sockets can be polarized - on sockets one slot is wider than the other, and unearthed (2-pin) plug may have one slit wider (that's neutral) than the other (that's hot).
The 2-pin plugs can then choose to be
- polarized (make one wrong wider)
- not polarized.
Most modern devices don't care and have plugs have prongs the same size.
And 3-pin plugs often don't need to bother(verify) with the different sizes, because the presence of the ground pin enforces the polarity. The 3-pin sockets specifically do, though.
Some plugs have holes in the prongs. This is not, as commonly believed, designed for more friction, or to slot into anything.
It's for alignment during manufacturing. In fact, NEMA seems to intentionally spec that if they're there, they should specifically be away from the actual mating part of the surface, so that it doesn't reduce contact area. 
Type F / Schuko / CEE 7/4
Type F plugs/sockets, also known as Schuko (short for Schutzkontakt, roughly meaning 'protective contact', referring to having a contact for protective earth), and formally CEE 7/4, are round sockets/plugs with two earth clips on the side, and two guides for a more robust fit in the embedded socket.
It is used in much of (western) Europe, commonly seen in wall sockets and power strips.
Not polarized, though there is an Argentinian variant that is.
CEE 7/7 plugs
Not a specific country's standard, but worth mentioning because it is designed to work in multiple, in that they are earthed plugs specifically designed to mate with both:
- Type F style earth (most of western Europe) and
- Type E style earth (France, Belgium, also Poland, Czech Republic, Slovakia, Denmark).
Seen in wires that must be earthed (so can't be europlugs) and meant for wide sales (that is, catching both type E and type F countries with the same plug). One good example is computer power supply cables, which are usually CEE 7/7 to C13.
Other, non-earthed European plugs: Type C, CEE 7/16, CEE 7/17, Europlug
The CEE 7/17 plug is a something of an unearthed adaptation of 7/16 to mate with Type E, Type F, and round type C sockets.
There is a (fairly rarely seen) socket that accepts no earthed plugs, by being a type E socket but instead of an earth pin, have a plastic pin and a strip of plastic from where it would be all the way to the edge. This seems to be used on 2-wire extension cords, to make sure you can't plug in an earthed appliance and forget that it isn't actually earthed (...and possibly to be legal to sell at all(verify)).
Type C exists in round and flat variants.
flat type C, also formalized as CEE 7/16, and regularly called a 'Europlug', is an unearthed plug that fits most European-style sockets (Type C, E, F, others).
Some power strips have a few thin-type-C sockets (and Shuko otherwise), because you'll always have a few devices with these and it saves space in that case (and in that case only, as these sockets accept nothing else).
There is also an unearthed round Type C - socket is CEE 7/1, plug is CEE 7/2.
While the socket (7/1) will accept most any European-style plugs (C, E, F; 7/4, 7/7, others), the round type C plug (7/2) will only really plug into the 7/1 socket, and roughly nothing else - it will not plug into Type E or F sockets (blocked by the plastic that guides the earth).
New installations will use earthed sockets, so the 7/1 socket is barely sold anymore.
Both mean that round type C has become rare both in plug and socket forms (unearthed european plugs are now often europlug or CEE 7/17 (see above), unearthed sockets are just uncommon).
Seen mostly in France, Belgium, Poland, Czech Republic, Slovakia, Denmark
Looks much like Type C, except for the male ground pin that sticks out.
While it has a fixed orientation, there is no polarization standard. (possibly because that would not apply to other european-style plugs it is fairly compatible with)
Also compatible with others, including (mostly things specifically designed for C, E, and F sockets)
- 7/7 plugs (european earthed round plugs)
- 7/17 plugs (the unearthed but still roundish one)
- and 7/16 plugs (flat unearthed europlug)
Type G, BS 1363 (UK)
Used in the UK and a dozen other countries
- polarized in the standard (though many everyday devices won't care)
- Earth prong is longer, so a device is earthed before it gets power
- Sockets may have safety shutters (actuated by the longer earth prong)
- Newer variants have the non-ground pins half shielded so it's very hard to reach live copper
Other apparent design considerations:
- All sockets are the same (there is no unearthed socket design)
- Fuses in the plug - often easier to replace than those in the devices
- Wire from bottom means people won't often try to pull it out from the wire, so few break that way (though possibly more break unintentionally)
BS 1363 replaced the earlier BS 546 in the 1940s, 1950s. BS 546 is still in use elsewhere, see Type D, M
There is also a distinct shaver socket, BS 4573, which looks like a thicker variant of europlug.
(Australia, New Zeakland, China, Argentina)
South Africa, and a variant seen in Brazil
Switzerland, also seen in Lichtenstein
Italy mostly sees type L, C, and F
Phase and neutral distance and pins compatible with Schuko/europlug.
Earth is a half-round pin on the plug,
Danish grounded plugs will only fit into a grounded socket.
However, non-Danish european plugs (type E, type F) plugs will mate, but without connecting ground.
Less-common Danish variants include
- one pin flat, used in hospitals
- phase and neutral pins slanted, for computer equipment, though reportedly this is more annoying than it is useful.
Type D, M
BS 546 is the older british plug, and also seen in India, Pakistan, some East African countries, South Africa,
Note that these countries may have other plugs. For example, it seems that:
- India sees C, D, and M
- Pakistan mainly sees C and D
- South Africa sees C, D, M, and N
Three round pins.
There are three different plugs, with larger pins spaced further apart, each with their own current rating.
Because of the three distinct sizes, the three varied plugs will only plug into a socket rated for the same current, although there are sockets that take multiple variants.
The 2 A and 5 A plug are considered Type D, the 15 A plug Type M.
When does wall polarity matter?
Power - industrial and multiphase interconnects
IEC 60309 (Europe)
Typical for lightbulb/pear shapes.
The number is the outer diameter of the metal screw part in mm.
There's quite a few of them, but by far most common are:
- E26/E27 - common large screw variant
- Apparently there's a correlation where E26 is for 120V countries and E27 for 230V countries(verify),
- they're physically close enough to often fit (verify)
- The more common small variant is usually E14 (Europe) and E17 (US) (verify)
There are a handful of other diameters in use, e.g.
- E11 (Europe), E12 (US) 'candelabra'
- E10 (miniature) in older flashlights, indicator lights, older bike lights
- uncommon now in all those uses, because e.g. LED is more efficient than incandescent
- E39/E40 (giant/'mogul') in industrial / older stage lighting
There are also a whole bunch of adapters, because within the same country it's the same voltage, and you might want a different style of lamp, deal with specific or chandeliers, etc.
bi-post / bi-pin
Many bi-post are IEC 7004 (verify)
You may like overviews from image searches for terms like light bulb socket types diagram
The number specifies the pin distance. Each distance tends to have a unique socket/plug design, in part to make them more easily identifiable.
Variants with smaller distances are typically small spots (classically halogen), for example:
- GU10 - pins, 10mm distance, widened bayonet-style end (seems to be one of only a few G variants that has that bayonet)
- GX5.3 - pins, 5.33mm distance
- G4 - pins (4mm distance, thinner)
- G9 - flat loops, 9mm between the centers of the loops
These may be easy to find in supermarkets and such - though the exact set varies a little with where you live.
Larger variants like
On relations to the bulbs
A few further details/associations are specified by the letters, e.g. G, GU, GX, GY, GZ.
For example, GZ bulbs use dichroic glass, which means the glass conducts and dissipates heat, so lets out much of the heat at the back.
Power and beam angle may wel be specified  though have some inconsistencies in specification.
While endless combinations between socket, bulb, and voltage could exist, there is a lot of consistency in : what is actually produced at all
- what type of bulb, reflector, and voltage is used on each connector
...so in practice most most further details are (only) implied from most specific references being unique(verify).
- GU4 are often 12V MR11 bulb
- GU5.3 are often a 12V MR16 bulb
- GU10 are often mains-voltage MR16 (as are various others with >7mm pin spacing)
- GZ10 is like GU10 but does not have a beveled base, which means you can't use GZ10 in GU10 sockets (but can the other way around). The reason seems to be a heat/safety restriction: GU reduces heat to to the rear/socket, GZ does not.
- G6.35 (1mm thick pins)
- GY6.35 (1.25mm thick pins)
- GY6.35, G8, or G9 are more frequently JCD type.
- G9 is often mains, G6.35 is often low-voltage
But don't count on this, because there are exceptions
Shapes and reflectors
- JC, JCD
Refers to a shape - just the small halogen bulbs, no reflector. Can be 12V, 24V, or mains voltage.
Comes in a few base sockets, often one of G6.35, G4, G8(verify)
Apparenly frequently semi-permeable glass, which is why you shouldn't touch it with your oily fingers.
- MR, Multifaceted Reflectors
MR bulbs are mostly associated with G-style bases, including GU10, GX5.3, and G4.
The number in MRsomething is the bulb diameter - in eighths of an inch, so MR16 bulbs are 5.1cm in diameter, MR11 are 3.5cm.
The combinations of diameter and socket aren't unique - which means it's fairly easy to walk into a store and buy a MR16 and discover you needed one with a GU10 and GU5.3 base and got the other.
You sometimes see specifications of diameter as well as power and beam angle - see .
- On voltage
Different MR bulbs may be 12V (most) or higher voltage (some), so never blindly assume.
12V may still be AC, though are often DC in practice.(verify) LED-based MR-series often won't care since they need to rectify anyway.
Some of the 12V (switch-mode) adapters designed for a string of halogen MRs will not like the low power draw of LED variants. You need a transformer that is not trying to be clever, one designed for lower draw, attach more lights on a single adapter, or get one designed with LEDs in mind.
See also DIY_optics_notes#Stage_lighting.
Exists in a number of variations
- XLR3, seen as:
- XLR5 - in the DMX specs (while many simpler DMX devices use only XLR3, XLR5 is somewhat common on pricier DMX devices)
...and various others, some of which are considered obsolete.
The two most recognisable uses are probably in the event industry:
(also note that audio cables and DMX cables, while they look similar, are not interchangeable for other reasons. It'll work on a test-bench scale, but give issues on large scale)
There are also some lesser-seen and specific variants, such as
- PDN to go between amps and speaker
- LNE, that carries just mains power, but was apparently never really used
See also The_XLR_pin_1_problem
Small mic plugs
There are some small, XLR-looking plugs and sockets seen on worn wireless microphones, some field recording kit, and is otherwise fairly rare.
These seem to be used for being a locking plug that is fairly solid.
It seems that plugs can vary per manufacturer, pinouts can vary even if the same connectors are used (varying a little by brand and context), and some aren't even differential (not as necessary for short cables).
This seems to frequently be the plug called Switchcraft TA3 (The female TA3F on the microphone end).
There is also a variant that uses TA4 (4-pin, TA4F on the microphone end), also with slightly varying pinouts.
Audio Technica seems to use a Hirose 4-Pin connector
There are others. The wiring link below seems a decent list.
Neutrik Combo is a single socket that accepts both XLR, and TS or TRS 1/4" (6.35mm) jacks, mainly used to save some space.
Neutrik Speakon is used in some professional audio, as a amp-to-speaker connection of an already amplified signal.
It seems to have been introduced to be a non-confusable plug, where before you'd have TS plugs that could carry either a signal or powered signal, which has the issue that plugging a powered output into a signal input could damage that input (though it's not too hard to protect against, e.g. with a varistor(verify)).
XLR was also sometimes abused this way.
Neutrik's powerCON is a few related connectors that connect mains power (20A or 32A), using a smaller plug than e.g. IEC connectors.
Some variants are rated IP65 when connected, which makes them useful for outdoor events.
Low power or signals
Sure, there are many things you can abuse the other way, but there are also things that are more designed (or more accidentally quite fit) to carry both low current power, or signals.
The banana plug is named for the curve that comes from the lengthwise springs that friction-lock the plug.
Actually, shapes vary, and not all 4mm plugs have a friction-lock design, but many do.
Length was typically 20mm, though e.g. the US seems to use 15mm, and there's more variation.
They are rated for something like 30V, 15A. It seems the main reason for the low voltage is not isolation in the arcing sense, but safety in the sense that the thing is entirely exposed.
The ones with fixes shrouds, or sleeves that retract, may be rated for higher voltages.
The 4mm version often carries lowish-current power or occasionally audio - it is seen on things like
- measuring devices, such as multimeters, bench power supplies, and such
- these are often also stackable somehow (4mm hole in the back, or side)
- and e.g. banana-to-BNC for oscillosocopes (handy for non-HF frequency measurements)
- amp/speaker connections
- easy to replug
- capable of dealing with moderate current
There is a 2mm plug seen in similar situations - seemingly mostly multimeters, probably because it's a nice tradeoff in study enough to not break, and thin enough to poke at many smaller components.
It's not really referred to as a (variation of) banana plug, because the lengthwise springs are not there, but I haven't found a better place to group it under.
Crocodile clips / Alligator clips
Crocodile clips are useful for making a temporary electrical connection that will be decent and stay on.
The ones in the image here are a few cm large and don't carry much current. Two of these plug onto banana plugs, for ease of use with multimeters.
There are large ones, seen e.g. around car batteries, that are much beefier.
Test hooks / pincer clips / IC grabbers
...and probably other names.
Details vary, but generally these are small grabby springy things extend and separate when opened by hand, and pull in and close when you let go.
This gives you good temporary connections on things like small pins, and won't touch each other when cramped like e.g. alligator clips would.
The image shows a very cheap variant (one extended), but they still work pretty well.
A set of spring loaded pins.
Mostly used in automated testbeds, where a PCB is pressed into a good number of these.
Smaller JST connectors
JST refers to a company that makes many series of plugs.
The below are mostly used as PCB (inter)connectors useful for data signalling, though many are rated for (on the order of) 1, 2, or 3A, so also useful to transfer some power.
A few of the series:
JST VH series
keying/mating: thinner on one side, slots to the side, clip
Rated for 10A (with AWG16)
Pitch: 2.5mm pitch
Pins: 2 (not a series)
keying/mating: round shape that guides into shell
Seen in RC vehicle applications, there known as JST connector, BEC connector, P connector(verify)
JST XH series
Pins: 2 to 20
Keying/mating: two slits near the side of one long end, with some slight bayonetting (works out more as a friction thing)
Perhaps most recognized as the connector on lithium batteries (verify) (2 or more pins depending on how many cells, for balance charging)
JST PH series
Pitch: 2.0mm pitch
Pins: 2 to 16
Keying/mating: socket has part of one side open, plug has slits keying for that side
JST EH series
2.5mm pitch, pairs with one unshrouded side
Pins: 2 to 15
Keying/mating: socket one side open, plug one side wider; slits on short edges
JST SM series
Pins: 2 to 18
Keying/mating: locking clip and keying on middle of one long side
"SM2 connectors" seem to refer to the 2-pin variant(verify)
JST ZH series
Pins: 2 to 13
Keying/mating: two slits on the sides (the shortest ends)
JST SH series
Pins: 2 to 20
Keying/mating: slits on side(verify)
Smaller molex connectors
Pitch: 2.54mm Pins: 2 .. 36 Keying/mating: slits around socket's wall, ridge along wall for friction
Pitch: 3.96mm Pins: 2 .. 24
Pitch: 5.08mm Pins: 2 .. 12
Micro and pico variants
- 1.25mm pitch
- molex picoblade
Smaller AMP connectors
(The company is now TE Connectivity, previously Tyco Electronics, and AMP far before that, but we tend to still call them connectors AMP)
- single row, 0.1" / 2.54mm pitch
- single row, 0.156" / 3.96mm pitch
It's a basic idea implemented in different ways by various companies. ...which is probably why there are also snap-in, bayonet, push-pull variants, various types of keying, and more variations.
In my (very biased) recollection I've seen the metal variants more around larger and industrial machines, probably because they're a way to have a sturdy, many-pin, and somewhat isolated control signal interconnection.
Device producers may favour one of them internally, so you probably see some of these more consistently than others)
Entire fields may too - there's e.g. the GX series connectors seen fairly consistently around aviation, usually smaller and fewer pin (I see mention of GX16, GX20, GX12, the number is the barrel diameter in mm)
....down to some cheap plastic (but waterproof) connectors seen around garden/christmas lighting, distinctly keyed (which in a few examples I found correlated with the voltages used).
...and apparently everything inbetween.
Mounts, chip carriers, packages, board connectors
Mounts, chip carriers
Packages refer to the specific design and size of something a particular component is housed in.
You will often see specific component types (and particularly specific models) in certain specific packages/mounts. For example, transistors are often seen in SOT or TO, diodes often in DO, LEDs often in what seems to be called T1, and so on.
Surface mount which may seem recent but has been around since the sixties. Surface mount has introduced a lot of specific smaller packages. It's hard to summarize them and give a decent impression of which are more common.
Pitch refers to the spacing of pins (more often mentioned in through-hole components, as those are fairly wide-purpose, while suface mount components tend to be more specialized packages)
Common pitches include
- 2.54mm (0.100")
- 2mm (0.079")
- 1.27mm (0.050")
- 0.8mm (0.031")
- 0.5mm (0.019")
There are a number of different measures that can be relevant in addition to pitch.
SMD/SMT versus though-hole
There is a noticable distinction in through-hole versus surface mount:
SMD (Surface Mount Devices) and SMT (Surface Mount Technology) often means leads that end flat on the circuit board, to be soldered in place (often with reflow soldering, wave soldering, or such).
SMD seems to have become popular since approximately the eighties. There are SMT variants of ICs, resistors, capacitors, and various other sorts of packages.
SMD/SMT can also be seen as the top of a hierarchy of a load of specific packages.
The style it is replacing has been (retroactively) named though-hole, occasionally abbreviated to THT (though-hole technology).
Packages, roughly from fewer to more leads
TO, SOT, SC, some small SMD
TO, SOT, SC, SOD refer to a style of making packages, all with quite a few variants, and usually with a small pin-count (often between 2 and perhaps 7, usually between 3 and 6).
While they have names referring to specific uses and sizes (TO: 'transistor outline', SOT: 'small-outline transistor', SOD: 'small outlide diode'), most of these packages end up seeing many other uses - particularly those packages that handle more than average power (heat).
Note that a number of specific packages have names in more than one of these series.
Many of these are THT, some SMT, some usable as both as they have long pins (some bending involved for THT).
TO ('transistor outline')
TO is often used when there is power involved (mostly because of the package's thermal capacity), e.g. for transistors, regulators, darlingtons, power resistors.
Specific TO packages include:
- TO-220 (images) (good heat dissipation, frequently used where power is involved)
- TO-236-AA (resembles SOT-23, but sizes are a little different)
- TO-252(-AA), a.k.a. DPAK (4.6mm pitch)
- TO-263(-AB), a.k.a. D2PAK (effectively 5.08mm pitch, because the middle isn't a pin(verify))
- TO-262 a.k.a. I2PAK
- TO-251 a.k.a. IPAK
SOT ('Small Outline Transistor')
A surface-mount package, used for transistors, but also rectifiers, regulators, and more.
There are quite a few variations, many with pins that are wider for better heat transfer.
- SOT-23 - with different amounts of acually present pins, sometimes referred to as:
- SOT-223 (three-terminal)
- SOT-232 (three-terminal)
- SOT-416 (SC-75) (three-terminal)
- SOT-723 (three-terminal)
- SOT-883 (three-terminal)
SC looks like SOT, but has thinner leads (verify)
THT-style diodes are often seen in DO-xx, for example
LEDs often in 
- the circular plastic housing is often mentioned just by its radius, though seems to also be called:(verify)
- T-1 (3mm)
- T-1 3/4 (5mm)
- T-3/4 (2mm)
seems to be called T1(verify) (but more commonly mentioned just by its radius)
- flat housings (THT connectors)
Single Inline Package. Regularly 0.1" pitch. Hardly a package at all.
Pitch: 2.54mm (most variants)
DIP (also DIL): dual in-line package, usually for ICs which need relatively few pins (up to 64 or so, usually fewer).
DIP often implies 0.1 inch (2.54 mm) pitch.
Most DIP chips have a row spacing of either 0.3 inch (7.62 mm) or 0.6 inch (15.24 mm). DIP is now often assumed to be 0.3" (which is also sometimes called skinny DIP(verify)).
Since DIP is largely about pin spacing, many things besides ICs can use or be compatible with DIP, or make DIP sockets useful for other things than DIP ICs.
SOIC (Small-Outline Integrated Circuit)
Pin count variation:
There are wider variants.
Pitch: 1.27mm (verify)
SOIC with J-type leads (instead of gull-wing leads).
Pitch: 1.27mm, and also 0.80mm, 0.65mm, 0.5mm, 0.4mm
- TSOP (Thin Small Outline Package) 
- pitch: 0.5, 0.55, 0.65, 0.8, 1.27mm
- SSOP (Shrink Small Outline package) 
- pitch: 1.27mm (verify)
- TSSOP (Thin Shrink Small Outline Package) 
- Pitch: 0.65mm
- VSOP (Very Small Outline Package) 
- 0.65 mm
- MSOP (mini SOP)
- Pitch: 0.65mm
- QSOP (Quarter size SOP) 
- Pitch: 0.625mm (25 mils), usually
- µSOP (micro SOP)
- Pitch: 0.5mm
- HSOP - SOP with heat wings
- HSSOP - SSOP with heat wings
PLCC (Plastic Leaded Chip Carrier)
PLCC chips have leads that wrap around the side and under the IC; the side allows it to be seated in a PLCC socket (can be handy for replacement ability, or when heat is critical), and it can also be soldered to surface-mount pads.
PLCC sockets have slot across one diagonal, these are for the specific PLCC extractor that eases removal of PLCC ICs.
Was also used in early CPUs, after DIP and before more specialized sockets.
Actually sits in a group called JLCC (J-Leaded Chip Carrier), subdivided into:
- PLCC (Plastic ~), which seems much more common of the two
- CLCC (Ceramic ~), which seems used mostly for in some high-temperature and prototypes(verify)
Micro Leadframe, Flat No-lead
Quad Flat Package is a number of
Pitch: 0.80mm, 0.65mm, 0.5mm, 0.4mm, 0.3mm (more?)
Pitch: 2.5mm, 1.27mm
Plastic or ceramic (PPGA, CPGA)
Pitch: 1.5mm, 1.27mm, 1.00mm, 0.8mm, 0.5mm
Unsorted chip mounts
('PCB connectors' is probably not the best name, I'll think of another)
Known variably as pin headers, just headers, as breakaway headers, as and under various other names.
Often 2.54mm (0.1") pitch.
Also the things that jumpers (sometimes known as shunts) sit on.
And you could call a row of headers a Single In-Line package (SIP) without too much of a stretch.
PCB headers are a fuzzy, wider concept, and can refer to pin headers as well as many more specific deivations, then often seen in shrouded and/or keyed (notched) form.
One simpler example is KK-family molex, which mostly add bits of plastic as polarity protection but will fit on basic headers as long as they have the same pitch.
PCB mount screw terminals
Screw terminals in general may be little more than screw to fasten down a wire to a metal plate.
The variant for PCBs, with pins you can solder, is usually also shrouded.
Bootlace ferrules, also known under a few other names (and comparable to a few variants of crimp pin) are sleeves meant to crimp onto stranded wire.
They contain all strands (and avoid some issues with a single strand making contact you don't want), and mean that screw terminals won't damage the strands.
Compare also to butt splices
Euroblock, also known as Phoenix connector, has screw terminals on one side and a snap-in connector on the other.
It can be convenient and fast working on semi-permanent setups.
It seems mainly used around few-wire control signals (e.g. RS-485) and audio setups.
DIN 41651 (image search) includes various series of fairly common insulation-displacement connectors, including IDC.
Usually two-by-many pins, also seen in four-by-many.
Often 2.54mm (0.1") pitch, smaller variants exist.
- With or without alignment notch (verify)
- With or without strain relief
- With or without latches
DIN 41612 / IEC 60603-2
"DIN 41612" OR "IEC+60603-2" (image search) resembles DIN 41651 (IDC and such), but applications are more specialized, and often has more connections (dozens is not unusual, up to over a hundred).
Commonly two-by-many or three-by-many pins.
Used by some pluggable rack systems, e.g. VMEbus, which is why a lot of image hits will be the 3x32 variant.
Flexible flat cable (FFC)
Could refer to any cable that is flat and flexible, but FFC usually refers to a fairly specific type commonly seen used as pluggable interconnects in tight spaces such as inside laptops and phones.
Seen in various colors - gray, black, white, transparent brown/orange, and others (color can correlate somewhat with size/pitch).
Common pitches include 0.5mm, 1 mm, 1.25mm, 2 mm. Thinner than ribbon cable.
FFC connectors often refer to the PCB sockets that accept the end of these cables, although complex designs may opt for specific connectors that take less space.
Related are Flexible Printed Circuits, which are circuits built fairly directly onto these cables (often using small SMD components, and often fairly simple circuits).
(Card) Edge Connectors
Refers to connections where one side is part of the PCB itself, with traces going to the edge in regular spacing, meant to plug into a spring connector socket,
That socket is often either fixed on a PCB (consider RAM, PCIx and similar), or sometimes in the middle of a cable (consider 5.25" floppy drive connectors)
- various buses for expansion cards (ISO, PCI, AGP, PCIx, etc.)
- various game ROM cartridges (NES , Sega, N64, etc.), Gameboy, DS, Switch
- some gray area -- many memory cards do not technically qualify - they look the same as these cartridges, except that the contacts are often not traces on a PCB
- 5.25" floppy drives (two-sided, 34-pin)
- RAM modules (rather smaller pitch)
A lot of these are two-sided, but simpler cases are not
Broadly refers to anything that does many-channel signaling between distinct circuit boards.
Can refer to
- setups that directly fit boards together (often fairly specialized, small, pin-dense connectors)
- things only useful for board connectors, like FFC
- wire-to-board used to connect boards, like IDC
Specific physical layouts like Arduino shields, mikroBUS
- ...and the below
Elastomeric connectors, a.k.a. ZEBRA strips,
Moderately narrow-use but not single-use
The grove connector is defined by seeed studio.
It's a 4-pin, 2mm-pitch connector (not a JST or molex plug, apparently NSTech PITCH 1125?)
They're basically a specific standard pinout to make quick prototyping easier.
Pinout seems to be
- VCC (5V or 3.3V depending on context)
...where the signal pins may be wired one of
- digital IO - two adjacent digital pins
- analog IO - two adjacent analog pins
- UART - RX, TX
- I2C - SCL, SDA
- no SPI?(verify)
Each grove socket is wired to just one of these, so it's more of a convenient socket than universal in the sense of 'plug in and it will work', and you still want to think about what the device behind this is capable of.
Also e.g. consider that digital pins may overlap with UART or may be PWM capable.
Bee series socket
Two two rows of 10pin 2mm pins.
The socket is used on some Arduino and related boards (e,g, lilypad, seeduino stalker, dfrobot leonardo, waspmote).
Two 8-pin 2.54mm pitch sockets carrying:
- 5V, 3.3V, Ground
- pin that supports interrupts (where possible)
mikroBUS is an open-standard socket from mikroElektronika that is meant to allow various sensors to be more plug and play
It does not seem very common beyond Click boards (which seems to be their own brand), but there's a whole bunch of them, so this certainly has its uses.
It can help that, because you can have adapters to arduino, raspberry pi, and some other DIY boards, it works as something as a platform-agnostic pin adapter.