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The EIA RS-232 Standard describes an electrical interconnection system for low speed serial communications. The standard stipulates the use of a subminature D connector with 25 pins (the DB 25-pin) connector. However, RS-232 compliant-transmissions can also be found using DB 9-pin and RJ45 connectors. The following table shows which signals are assigned to which pins in the various cabling systems.
| DB 25-Pin | DB 9-Pin (IBM PC subset) |
DIN 8-Pin (Macintosh subset) |
RJ-45 8-Pin |
Common Symbolic Name |
ITU/CCITT Circuit Name |
EIA Circuit Name |
Signal Direction |
Signal Function | |
| 1 | 5 | FG | 101 | AA | Ground | Frame Ground | |||
| 2 | 3 | 3 | 3 | TD | 103 | BA | To DCE | Transmitted Data | |
| 3 | 2 | 5 | 4 | RD | 104 | BB | To DTE | Received Data | |
| 4 | 7 | 1 | 8 | RTS | 105 | CA | To DCE | Request to Send | |
| 5 | 8 | 7 | CTS | 106 | CB | To DTE | Clear to Send | ||
| 6 | 6 | 2 | DSR | 107 | CC | To DTE | Data Set Ready | ||
| 7 | 5 | 4,8 | 1, | 2 | SG | 102 | AB | Ground | Signal Ground |
| 8 | 1 | 2 | 5 | DCD | 109 | CF | To DTE | Data Carrier Detect | |
| 9 | |||||||||
| 10 | |||||||||
| 11 | QM | Bell 208A | To DTE | Equalizer Mode | |||||
| 12 | SDCD | 122 | SCF | To DTE | Secondary Data Carrier Detect | ||||
| 13 | SCTS | 121 | SCB | To DTE | Secondary Clear To Send | ||||
| 14 | STD | 118 | SBA | To DCE | Secondary Transmitted Data | ||||
| 14 | NS | Bell 208 | To DCE | New Sync | |||||
| 15 | TC | 114 | DB | To DTE | Transmitter Clock | ||||
| 16 | SRD | 119 | SBB | To DTE | Secondary Received Data | ||||
| 16 | DCT | Bell 208 | To DTE | Divided Clock Transmitter | |||||
| 17 | RC | 115 | DD | To DTE | Receiver Clock | ||||
| 18 | DCR | Bell 208 | To DTE | Divided Clock Receiver | |||||
| 19 | SRTS | 120 | SCA | To DCE | Secondary Request To Send | ||||
| 20 | 4 | 1 | 6 | DTR | 108.2 | CD | To DCE | Data Terminal Ready | |
| 21 | SQ | 110 | CG | To DTE | Signal Quality Detect | ||||
| 22 | 9 | RI | 125 | CE | To DTE | Ring Indicator | |||
| 23 | 111 | CH | To DCE | Data Rate Selector | |||||
| 23 | 112 | CI | To DTE | Data Rate Selector | |||||
| 24 | TC | 113 | DA | To DCE | External Transmitter Clock | ||||
| 25 | Bell 113B | To DCE | Busy | ||||||
| DB 25-Pin |
This is the name for the 25-pin subminature D connector most
commonly-associated with RS-232 cabling systems. The subminature D connector
consists of gold-plated (or a related compound) pins organized in two rows.
The first row contains 13 pins numbered 1 through 13. The 12 pins in the
second row are numbered 14 through 25 and are offset from the pins in the
first row. When viewing the male DB 25-pin connector (contact pins facing
you), pins 1 and 14 are on the left. The matching female connector (contact
sockets facing you) has pins 1 and 14 on the right.
Until the IBM-PC was introduced, RS-232 signals were invariably provided via DB 25-pin connector systems. |
| DB 9-Pin |
When IBM introduced the IBM-PC in 1981, it offered a plug-in card containing
a parallel printer port and a RS-232 serial port. However, due to mechanical
size limitations of the plug-in cards that IBM used in this system (later
known as ISA cards), IBM elected to deviate from the established use of a
DB 25-pin connector for RS-232 use. Instead, IBM selected the nine most
commonly used signals in the RS-232 standard and provided them using a
DB 9-pin connector.
IBM sold translator cables which would allow traditional RS-232 devices to connect the IBM-PC. IBM apparently expected that peripherals which used RS-232 signaling would migrate to IBMs chosen nine-pin subset, but this did not occur. To this day, PC-compatible computer owners still purchase DB 9-to-DB 25 cables so that they can connect external modems and other serial devices to their computers. The DB 9-pin contains the signals on pins 1 through 8, pin 20 and 22, which are: TD, RD, RTS, CTS, DSR, SG, DCD, DTR and RI. This is considered "full" modem control for asychronous modems. Pins above 9 are mainly for synchronous signaling systems, or in cases where a primary and secondary data channel are used. Normally when DB 9-pin cabling are connected to full DB 25-pin cabling, SG and FG are connected together.
|
| Macintosh mini-DIN 8-pin | The Apple Macintosh computer used an eight-pin mini-DIN connector for its RS-232 serial connections. It uses a subset of signals similar to that used on the IBM-PC DB 9-pin connector, Apple elected to drop RI and CTS. |
| RJ45 |
The idea of using RJ45 cables for RS-232 signals first appeared in the
mid-1980s in PC-compatible computers running XENIX and similar multi-user
operating systems. The need to have more than one or two serial ports
per ISA slot required a higher connector density than the DB 25-pin or the
DB 9-pin
would provide. The earliest examples included as many as six RJ45 connectors
on the edge of an ISA card.
The signals selected for the RJ45 subset of RS-232 are identical to those used by IBM in the DB 9-pin, with the exception of Ring Indicator. The standard solid color code used in "satin-flex" telephone cabling and most pre-built DB-9 to RJ-45 or DB-25 to RJ-45 assemblies is shown in the table above. As viewing a RJ-45 connector with the pins facing up and the connector facing away from you (cable closest), the USOC numbering of the pins is from left to right is 4 5 3 1 2 6 7 8. So for an EIA 568A cable, pins 1 and 2 are Blue and White, pins 3 and 4 are White and Orange, pins 5 and 6 White and Green, and pins 7 and 8 are White and Brown. EIA 568B exchanges the positions of Orange and Green pairs, so pins 1 and 2 are Blue and White, pins 3 and 4 are White and Green, pins 5 and 6 are White and Orange, and pins 7 and 8 are White and Brown. In all cases, pairs are positioned so that the long (or solid) White color wire of each pair appears on every other contect, starting with the left-most contact. This means that the center pair (pins 1 and 2 ) have the Blue and White colors in reverse order than occurs in all other pairs.
|
| Common Symbolic Name |
These two, three or four-letter abbreviations for the various signals
frequently appear on status indicators and other markings that had limited
space available.
In this column of the table, these are color-coded by function. the color Red is used to indicate signals used for data, White for flow control, Orange for modem/carrier control, Purple for clocks, and Green for ground. Note that Frame Ground is sometimes known as Protective Ground with the symbol PG. |
| ITU/CCITT Circuit Name |
The ITU (formally the CCITT) elected to use numbers as designators for
each electrical circuit in the RS-232 signalling system. Some connectors
have no official designation, usually because AT&T was using that contact
in a similar connector for some function specific to a proprietary device
that AT&T sold. A perfect example is pin 11, which is used in the Bell 208A
modem to control the equalizers used to compensate for artifacts of the
loop that the modem was connected to. No subsequent RS-232 device needed
such a service controlled remotely, so the Bell 208A remains as the only
device that used pin 11 for anything. The ITU/CCITT and the EIA have
never designated another use for this pin, but they have re-used some
other pins that AT&T had used previously for other purposes.
|
| EIA Circuit Name |
The EIA (an American standards body) decided to create the RS-232 standard
(now in revision E or RS-232-E), and in their standard, they used letter
codes to identify each circuit in the RS-232 signaling system. The
assignment of function to pin were copied with few changed for the ITU/CCITT
standard.
|
| Signal Direction |
The signals are presented from the perspective of a DTE device, in that
it transmits data to a DCE device (such as a modem) on pin 2. This signal
is marked "To DCE".
DTE is the Data Terminal Equipment, such as a serial terminal or a desktop
computer.
In the table, DCE signals are color-coded Yellow, DTE signals are Blue and Ground signals are Green.
|
| Signal Function | A brief description of what the signal is used for. |
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