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Communication Specs

What is the "RS" in RS232/RS485/RS422?

Let's start out by talking about this nasty "RS" business. So, what the heck does the "RS" stand for? You had better sit down for this one. It means Recommended Standard. That's right! The RS stands for Recommended Standard. Nothing was really agreed upon or official. At least not in the sense of the "made-by-committee" standards like IEEE-1284 and IEEE-1394. However, today RS-485 is formally known as TIA/EIA-485, for the associations that oversee the specifications for electronics and telecommunications standards. Officially the standard is now TIA/EIA-485-A, you may purchase your own copy of the standards here. To see more interpretation of the standards and further information regarding RS-232/485/422 see our app notes section in this website.

What does this all mean? Because RS standards were merely recommended and technically general, lots of manufacturers develop products that are at best sub-standard. They cut corners and cheat in order to manufacture cheaper products.

We have tried not to make sub-standard products. That is why you don't see any port powered products put out by Integrity Instruments. Engineers have enough headaches the way it is!

Also to reach a better understanding of TIA/EIA/RS-485, read an article on RS-485 written by Bob Perrin for Circuit Cellar Online, July 1999. Read it here!

Simplex & Duplex

One of the most fundamental concepts of communications technology is the difference between Simplex and Duplex.

Simplex can be viewed as a communications "one-way street". Data only flows in one direction. That is to say, a device can be a receiver or a transmitter exclusively. A simplex device is not a transceiver. A good example of simplex communications is an FM radio station and your car radio. Information flows only in one direction where the radio station is the transmitter and the receiver is your car radio. Simplex is not often used in computer communications because there is no way to verify when or if data is received. However, simplex communications is a very efficient way to distributed vast amounts of information to a large number of receivers.

Duplex communications overcome the limits of Simplex communications by allowing the devices to act as transceivers. Duplex communication data flows in both directions thereby allowing verification and control of data reception/transmission. Exactly when data flows bi-directionally further defines Duplex communications.

Full Duplex devices can transmit and receive data at the same time. RS232 is a fine example of Full Duplex communications. There are separate transmit and receive signal lines that allow data to flow in both directions simultaneously. RS422 devices also operate Full Duplex.

Half Duplex devices have the dubious honor of allowing both transmission and receiving, but not at the same time. Essentially only one device can transmit at a time while all other half duplex devices receive. Devices operate as transceivers, but not simultaneous transmit and receive. RS485 operates in a half duplex manner

Side-By-Side Specification Chart

Here is the short version of the critical specifications. Unfortunately, these are subject to interpretation by individual manufacturers. That is why RS232 is often regarded as an incredibly non-standard communications protocol.

One important note. You will see that one of the major differences between RS232 and RS422/RS485 is the signaling mode. RS232 is unbalanced while RS422/RS485 is balanced. An unbalanced signal is represented by a single signal wire where a voltage level on that one wire is used to transmit/receive binary 1 and 0: this can be considered a push signal driver. On the other hand, a balanced signal is represented by a pair of wires where a voltage difference is used to transmit/receive binary information: sort of a push-pull signal driver. In short, unbalanced voltage level signal travels slower and shorter than a balanced voltage difference signal.

Side-By-Side Speciification Chart
  RS232 RS422 RS485
Cabling single ended single ended
multi-drop
multi-drop
Number of Devices 1 transmit
1 receive
5 transmitters
10 receivers
32 transmitters
32 receivers
Communication Mode full duplex full duplex
half duplex
half duplex
Max. Distance 50 feet at 19.2 Kbps 4000 feet at 100 Kbps 4000 feet at 100 Kbps
Max. Data Rate 19.2 Kbps for 50 feet 10 Mpbs for 50 feet 10 Mpbs for 50 feet
Signaling unbalanced balanced balanced

Mark (data 1)

-5 V min.
-15 V max.

2 V min. (B>A)
6 V max. (B>A)
1.5 V min. (B>A)
5 V max. (B>A)
Space (data 0) 5 V min.
15 V max.
2 V min. (A>B)
6 V max. (A>B)
1.5 V min. (A>B)
5 V max. (A>B)
Input Level Min. +/- 3 V 0.2 V difference 0.2 V difference
Output Current 500 mA
(Note that the driver ICs normally used in PCs are limited to 10 mA)
150 mA 250 mA

DTE & DCE

Let's talk about DCE (Data Communications Equipment) and DTE (Data Terminal Equipment) devices. The difference between DCE and DTE is largely in the Plug and the direction of each pin (input or output). Your desktop PC is termed as a DTE device.

DCE devices use a 25-pin female connector while a DTE device uses a 25 pin male connector. Also, complimentary signals lines like transmit and receive are "swapped" between the two types. Thus, a straight-through cable can be used to connect a DCE device to a DTE device.

DTE & DCE Comparison
DTE DCE
25 pin male pin-out 25 pin female pin-out
Pin 1 - Shield Ground Pin 1 - Shield Ground
Pin 2 - Transmitted Data (TD) output Pin 2 - Transmitted Data (TD) input
Pin 3 - Receive Data (RD) input Pin 3 - Receive Data (RD) output
Pin 4 - Request To Send (RTS) output Pin 4 - Request To Send (RTS) input
Pin 5 - Clear To Send (CTS) input Pin 5 - Clear To Send (CTS) output
Pin 6 - Data Set Ready (DSR) input Pin 6 - Data Set Ready (DSR) output
Pin 7 - Signal Ground Pin 7 - Signal Ground
Pin 8 - Carrier Detect (CD) input Pin 8 - Carrier Detect (CD) output
Pin 20 - Data Terminal Ready (DTR) output

Pin 20 - Data Terminal Ready (DTR) input

Pin 22 - Ring Indicator (RI) input Pin 22 - Ring Indicator (RI) output

You can effectively convert DCE/DTE devices by using a NULL Modem cable. The null modem cable swaps the complimentary signals and allows a DCE device to act like a DTE and vice-versa.

The following DTE specifications depict the cabling of the DB9 connector found on an IBM-PC type computer.

  • 9 pin male pin-out
  • Pin 1 - Carrier Detect (CD) input
  • Pin 2 - Receive Data (RD) input
  • Pin 3 - Transmitted Data (TD) output
  • Pin 4 - Data Terminal Ready (DTR) output
  • Pin 5 - Signal Ground
  • Pin 6 - Data Set Ready (DSR) input
  • Pin 7 - Request To Send (RTS) output
  • Pin 8 - Clear To Send (CTS) input
  • Pin 9 - Ring Indicator (RI) input


RS485 Multidrop Wiring Diagram

RS485 is sometimes termed as RS485 Multidrop LAN since it can connect several devices in a LAN network environment. These devices are all connected to a single pair wire. Transmit and receive share the same two wires.

Officially the RS485 specification allows only 32 nodes (devices) on the LAN. However, I.C. manufacturers have developed RS485 drivers capable of allowing 128 to 255 nodes on an RS485 LAN. We use these next generation RS485 drivers in our products. This means that you can use our Converters and Remote I/O devices in more expansive situations.

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RS422 Single Ended Wiring Diagram

RS422 is a "drop-in" replacement for most RS232 applications. It is full-duplex and capable of long distance communications.

422-wiring.gif

RS422 Multidrop Wiring Diagram

In our opinion, RS422 multidrop is a bozo-nono. Quite frankly it is a pain in the posterior because it is a mix of RS485 multidrop and RS422 single ended. In short, you get the worst of both worlds and a wiring headache to boot. There are so many variations to wiring multi-drop RS422, that we do not feel it would do any good to display them here. Let your imagination run wild!