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Subject: Frequently Asked Questions
for
Amateur Packet Radio
Version 1.5
4 October 1991
This document is for unlimited distribution.
Please send corrections and additions to Steve Schallehn
(steve@matt.ksu.ksu.edu). The Packet Radio FAQ's will be posted
on a monthly basis to rec.radio.amateur.packet. The current
version of this document is available via anonymous FTP at
ftp.cs.buffalo.edu.
1.0 Basic Packet Radio Information
1.1 What is packet radio?
1.2 What is amateur radio?
1.3 What can I do on packet radio?
1.4 Why packet over other digital modes?
1.5 What elements make up a packet station?
TNC (Terminal Node Controller)
Computer or Terminal
A radio
1.6 What do you mean we can all use the same channel?
1.7 What is AX.25 ?
1.8 Definitions: Commonly used terms in Amateur Packet
Radio
1.9 Do's and Don'ts : Rules and Regulations
2.0 Computing Network Resources for Amateur Packet radio
2.1 What Newsgroups/mailing lists are available?
2.2 What anonymous FTP sites are available
2.3 Are there any gateways for mail or news
Internet / Packet Radio BBS Gateway
LAN Gateways (Packet wormholes via Internet)
3.0 Networking and special packet protocols
3.1 Are there any other protocols in use other than AX.25?
3.2 What is TCP/IP?
3.3 Networking Schemes
What are some of those other networking schemes?
Digipeaters
KA-Nodes
NET/ROM
ROSE
3.4 BBS message transfer
1.0 Basic Packet Radio Information
1.1 What is packet radio?
Packet radio is digital communications via amateur radio. Packet
radio takes any digital data stream and sends that via radio to
another amateur radio station. Packet radio is so named because
it sends the data in small burst, or packets.
1.2 What is amateur radio?
Amateur Radio (sometimes called Ham Radio) is individuals using
specified radio frequencies for personal enjoyment,
experimentation, and the continuation of the radio art. Amateur
radio operators must be licensed by their government. In the
United States, the Federal Communications Commission issues
amateur radio licenses. Normally, a test on operating practices,
radio theory, and in some cases morse code proficiency test is
administered. Amateur radio is not to be used for commercial
purposes. Also, amateur radio operators are restricted from
using profanity and using amateur radio for illegal purposes.
For more information on Amateur Radio in general, see the monthly
frequently asked questions posting in rec.radio.amateur.misc.
1.3 What can I do on packet radio?
Keyboard-to-Keyboard contacts:
Like other digital communications modes, packet radio can be
used to talk to other amateurs. For those who cannot use HF
frequencies, 2 amateurs can talk to each other from long
distances using the packet radio network.
Packet BBS operations:
Many cities have a packet Bulletin Board System (BBS)
attached to their local packet network. Amateurs can check
into the BBS's and read messages from other packet users on
almost any topic. BBS's are networked together over the
packet network to allow messages to reach a broader audience
than your local BBS users. Private messages may also be
sent to other packet operators, either locally or who use
other BBSs. BBS's have the latest ARRL, AMSAT, and
propagation bulletins. Many BBS's have a file section
containing various text files full of information on amateur
radio in general.
DX Packet Cluster:
A recent development is use of packet radio for DX spotting.
HF operators connect to the local DX Packet Cluster for the
latest reports on DX. Often a user will 'spot' some hot DX
and distribute the DX report real time.
File Transfer:
With special software, amateurs can pass any binary files to
other amateurs. Currently, this is done with TCP/IP
communications, YAPP, and other specialized protocols.
Satellite Communications:
Many of the amateur radio satellites contain microcomputer
systems that can provide special information to amateurs.
Some satellites contain CCD cameras on board and you can
download images of the earth and the stars. Others provide
store and forward packet mailboxes to allow rapid message
transfers over long distances. Some satellites use AX.25,
some use special packet protocols developed for satellite
communications. A few transmit AX.25 packets over FM
transmitters, but most use SSB transmissions.
1.4 Why packet over other digital modes?
Packet has three great advantages over other digital modes:
transparency, error correction, and automatic control.
The operation of a packet station is transparent to the end user;
connect to the other station, type in your message, and it is
sent automatically. The Terminal Node Controller (TNC)
automatically divides the message into packets, keys the
transmitter and sends the packets. While receiving packets, the
TNC automatically decodes, checks for errors, and displays the
received messages. In addition, any packet TNC can be used a
packet relay station, sometimes called a digipeater. This allows
for greater range by stringing several packet stations together.
Packet radio provides error free communications because of built
in error detection schemes. If a packet is received, it is
checked for errors and will be displayed only if it is correct.
With VHF/UHF packet, many countries allow packet operators to
operate in automatic control mode. This means that you can leave
your packet station on constantly. Other users can connect to
you at any time they wish to see if you are home. Some TNC's
even have Personal BBS's (sometimes called mailboxes) so other
amateurs can leave you messages if you are not at home.
Another advantage of packet over other modes is the ability for
many users to be able to simultaneously use the same frequency
channel simultaneously.
1.5 What elements make up a packet station?
TNC (Terminal Node Controller)
A TNC contains a modem to decode the audio signals into
digital signals. It also contains a modem and a micro-
computer to convert the digital signals into text that can
be sent over a RS-232 port to the computer. The CPU also
handles the protocol overhead of the packet station. When
you send data, it takes the text, puts error checking on it
(CRC) and also puts it in an envelope for sending. When
receiving a signal, it takes it out of the envelope, and
sends the message to the computer.
Most TNC's use 1200 baud for local UHF/VHF packet and 300
baud for long distance HF packet communications. For
VHF/UHF packet, higher speeds modems are available, but
often are harder to interface.
Computer or Terminal
This is the user interface. A computer running a terminal
program or just a dumb terminal can be used. For computers,
any phone modem communications program can be adapted for
packet use or customized packet radio programs are
available.
A radio
For 1200 baud UHF/VHF packet, commonly available narrow band
FM voice radios are used. For HF packet, 300 baud data is
used over single side band modulation. For high speed packet
(anything greater than 1200 baud), special radios or
modified FM radios must be used.
1.6 What do you mean we can all use the same channel?
Packet radio uses a protocol called AX.25. AX.25 specifies
channel access (ability to transmit on the channel) to be handled
by CSMA (Carrier Sense Multiple Access) If you need to transmit,
your TNC monitors the channel to see if someone else is
transmitting. If no one else is transmitting, then the radio
keys up and the TNC sends it's packet. All the other stations
hear the packet and do not transmit until you are done.
Unfortunately, 2 stations could accidentally transmit at the same
time. This is called a collision. If a collision occurs,
neither TNC will receive a reply back from the last packet it
sent. Each TNC will wait a random amount of time and then
retransmit the packet.
In actuality, a more complex scheme is used to determine when the
TNC transmits. See the "AX.25 Protocol Specification" for more
information.
1.7 What is AX.25 ?
AX.25 (Amateur X.25) is the communications protocol used for
packet radio. A protocol is a standard for how two computer
systems are to communicate with each other, somewhat analogous to
using business format when writing a business letter. AX.25 was
developed in the 1970's and based of the wired network protocol
X.25. Because of the difference in the transport medium (radios
vs wires) and because of different addressing schemes, X.25 was
modified to suit amateur radio's needs. AX.25 includes a
digipeater field to allow other stations to automatically repeat
packets to extend the range of transmitters. One advantage of
AX.25 is that every packet sent contains the senders and
recipients amateur radio callsign, thus providing station
identification with every transmission.
1.8 Definitions: Commonly used terms in Amateur Packet Radio
HDLC : (High-Level Data Link Control Procedures) A standard for
high level link control. (ISO 3309)
AX.25 : Amateur X.25 protocol. The basis of most packet systems.
See section 1.7.
TAPR : Tucson Amateur packet Radio. Was the first group to
create a packet radio TNC using AX.25. Soon a TAPR TNC became
cloned by many others. TAPR continues development of packet
radio equipment.
digipeater : A packet radio station used for repeating packets.
See section 3.3.1 for more information.
digi : Short name for a digipeater
NET/ROM : A scheme for packet radio networking. See section
3.3.3 for more information.
TCP/IP : Transmission Control Protocol/Internet Protocol. A set
of utility programs used over AX.25. See sections 3.2 for more
information.
KA9Q NOS : (KA9Q Network Operating System) A TCP/IP program
originally developed by Phil Karn, KA9Q. Currently there are
many different versions available. See section 3.2 for more
information.
NODE : A network node. Often a network node running NET/ROM.
KA-Node : A simple networking scheme developed by TNC maker
Kantronics. See section 3.3.2 for more info.
CSMA : Carrier Sense Multiple Access. A system allowing many
stations to use the same radio frequency simultaneously for
packet communications.
TNC : Terminal Node Controller. See section 1.5 for more
information.
AMPR : Amateur Packet Radio.
44 net : The class A network designator for TCP/IP amateur packet
radio. All numerical TCP/IP addresses are in the format of
44.xxx.xxx.xxx .
ampr.org : The high level domain recognized on Internet for
amateur packet radio TCP/IP.
RS-232 : (RS-323C) A standard for interconnection of serial
peripherals to small computer systems. In packet radio, RS-232
is the most common interface between TNC's and the
Computer/Terminal.
protocol : A standard used for intercommunications between
different computer systems.
CRC : Cyclical Redundancy Code. The error detection scheme
included in each packet. Verify that the packet was received
error free.
KISS : Keep It Simple Stupid. A simple interface developed for
communications between TNCs and computers. This allows for most
of the packet processing to be handled by the computer. Commonly
used with packet TCP/IP software.
modem : Modulator/Demodulator. Converts the analog signals into
binary data stream (a series of ones and zeros) for the TNC or a
micro-computer . First step in decoding packets.
FCC : Federal Communications Commission. Regulates and issues
licenses for amateur radio in the United States.
FM : Frequency Modulation. The radio modulation scheme used for
VHF and UHF packet communications.
SSB : Single Side Band Modulation. The radio modulation scheme
use for HF packet and satellite packet communications.
AFSK : Audio Frequency Shift Keying. A method of representing
digital information by using different audio frequencies
modulated on a carrier.
FSK : Frequency Shift Keying. A method of representing digital
information by shifting the radio carrier different amounts to
represent ones and zeros.
LAN : Local Area Network. A packet network developed for
communications throughout a city or region. Often, the LAN uses
separate frequencies from inter-city packet links.
1.9 Do's and Don'ts : Rules and Regulations
NOTE: These regulations apply only to amateurs regulated by the
FCC (United States), but often are similar to regulations in
other countries.
[Since I have no experience with amateur radio in other
countries, I cannot make any comments. Please bring any notable
exceptions to my attention. -Steve]
Although there are no specific rules that apply to amateur packet
radio, the general amateur radio rules force some restrictions on
packet usage.
Can I set up a TNC at home and one at work so I can check my
Electronic mail via packet?
This cannot be done without special restrictions. Amateur
radio rules prohibit any business. Since you could have
mail from your boss (or maybe even someone selling you
something over Internet), that would constitute business
activity and is specifically prohibited.
Profanity can also be a complication. Since you have no
control over the language used in E-mail, proper filtering
is required. Since no filter scheme can catch every
offense, it is best to say every message must be hand
filtered.
I would like to set up a packet radio gateway between a land line
computer network and the packet network. Is this possible?
Yes, and there are several such gateways in use, but they
must be managed with caution. Electronic mail may be pass
FROM the packet network INTO the land line network without
intervention. However, mail passed TO packet radio is
considered third party traffic (the sender is not an
amateur) and these messages must be hand filtered to assure
that rules of message content are followed.
It's my license if I send use packet radio illegally anyway, so
what does anyone else care!
Packet radio is one of the few NETWORKED systems in amateur
radio. Many people have helped develop the network and
there are many amateurs who own parts of the packet radio
network. Sending packet BBS mail, digipeating, and sharing
the channel involves the licenses of MANY people. Because
of FCC rules stating that anything to come out of a
transmitter (either in automatic mode or via your direct
control) is the licensees responsibility, one illegal
message sent over the packet radio network could literally
jeopardize the license of thousands of other amateurs. When
in doubt, it is best to check with other amateurs about
sending the message before it is sent.
I have some ideas on how to use packet radio in a new way, but I
don't know if it is legal. Who could tell me if I can do it
legally?
The worst thing you can do is talk to the FCC about such an
issue. The FCC rules are written to be general enough to
encompass but not restrict new radio activities. In the
past, any non-thought-out requests sent to the FCC have
meant a reduction of privilege for all amateur radio
operators.
The best source for legal assistance is your national
amateur radio association. In the United States, that is
the American Radio Relay League (ARRL). Another good place
for such conversations is over Usenet/packet mailing lists,
or the amateur radio BBS network.
2.0 Computing Network Resources for Amateur Packet radio
This section summarizes the resources available on Internet for
amateur packet radio operators.
2.1 What Newsgroups/mailing lists are available?
This is a list of all groups that regularly discuss amateur
packet radio. For newsgroups, join the group through use of your
news reader. For mailing lists, add a '-request' to the end of
the list name to request subscriptions. For listserv groups,
send mail to 'listserv' at the node which contains the list. The
first line of the mail should be 'SUBSCRIBE groupname yourname'.
Send the command 'help' for more information.
rec.radio.amateur.packet (Newsgroup):
General discussions involving Packet Radio.
rec.radio.amateur.misc (Newsgroup):
General amateur radio discussion. Usually does not contain
any particular information about Amateur Packet Radio.
rec.radio.amateur.policy (Newsgroup):
Discussion of regulation policies regarding every aspect of
amateur radio. Occasionally deals with polices of packet
coordination and legal issues of packet radio.
rec.radio.swap (Newsgroup):
General For-Sale for any radio equipment. Occasionally will
have packet equipment for sale. Recommended location for
any amateur packet radio for-sale items.
info-hams@ucsd.edu (Listserv group):
A digest redistribution of the rec.radio.amateur.misc Usenet
discussion.
packet-radio@ucsd.edu (Listserv group):
A digest redistribution of the rec.radio.amateur.packet
Usenet discussion.
ham-policy@ucsd.edu (Listserv group):
A digest redistribution of the rec.radio.amateur.policy
Usenet discussion
hs-modem@wb3ffv.ampr.org (Mailing list):
Discussion of high speed modems and radios available and
future plans. Also includes discussion of networking using
high speed modems.
tcp-group@ucsd.edu (Mailing list):
Group discussion technical developments of TCP/IP over
packet radio and use of the NOS TCP/IP programs.
gateways@uhm.ampr.org (mailing list):
Discussion of current gateways and future plans for
gateways. May deal with sensitive internetworking issues.
For all lists at ucsd.edu, archives may be found via anonymous
FTP at ucsd.edu. Some listserv groups also have archives. Send
the command 'help' to the group's listserv for more information.
Digest mailings for the ucsd.edu discussions are also available.
Send mail to listserv@ucsd.edu with the first line being
'longindex' for more information.
2.2 What anonymous FTP sites are available for getting packet radio
information and programs?
This is a sampling of FTP sites that carry amateur packet radio
related files. Consult the Archie archive server for info on
locating particular files. For more information on using archie,
send mail to archie@cs.mcgill.edu with the line 'help'.
ucsd.edu
Primary distribution site of KA9Q's derived TCP/IP packages.
Also, general packet radio information.
wsmr-simtel20.army.mil
Very large collection of amateur radio software.
wuarchive.wustl.edu
Mirror site of Simtel20 archives. Unix directory
structure - Easier to use then the simtel20 archive.
ftp.cs.buffalo.edu
Supplimental archive site for amateur radio information.
Contains current copies of all rec.radio.amatuer.* FAQ's.
tomcat.gsfc.nasa.gov
Packet software including Baycomm, Rose, G8BPQ, NOS, etc.
2.3 Are there any gateways for mail or news between Internet and
Amateur Packet radio?
Internet / Packet Radio BBS Gateway
Jim Durham, W2XO, maintains a gateway between Internet and the
Packet radio BBS system.
To mail from Internet to Packet:
1. Mail to: "bbs@w2xo.pgh.pa.us"
2. Make the first line of the text a Packet BBS "send"
command, ie:
SP TOCALL @ BBSCALL.ROUTING-HINTS < FROMCALL
3. The "subject" line of the Internet mail becomes the
"title" line of the Packet BBS mail.
NOTE: Because of FCC regulations, Jim must hand filter each
message sent FROM Internet TO the Amateur Packet Radio
BBS system. Messages should be of minimal length and
appropriate content. Read Section 1.9 (Do's and
Don'ts: Rules and Regulations) regarding appropriate
usage of packet radio for more information. Always
include the routing hints with the BBS callsign.
To mail from Packet to Internet:
1. The amateur radio operator must have his callsign
registered in the gateway alias list. If you want to
mail from packet to a specific amateur on Internet,
send mail to 'durham@w2xo.pgh.ps.us' (Internet) or
'W2XO @ W2XO.#WPA.PA.USA.NAOM' (Packet BBS mail) with
his/her amateur callsign and their Internet address.
2. Once the above is accomplished, packet BBS mail should
be sent to 'CALL @ W2XO.#WPA.PA.USA.NAOM'. The mail
will automatically be forwarded to the Internet address
of the amateur with the 'CALL' callsign.
Jim Durham's Internet address is 'durham@w2xo.pgh.ps.us'.
LAN Gateways (Packet wormholes via Internet)
Currently a group of amateurs are experimenting with connecting
packet LANs together via Internet IP inside IP Encapsulation.
Some of the gateways only accept TCP/IP packets, others AX.25
packets. These gateways uses the Internet as a transport medium,
thus it is impossible to access the packet radio network from
Internet. For more information, join the Gateways mailing list
by sending mail to "gateways-request@uhm.ampr.org".
3.0 Networking and special packet protocols
This is a sample of some of the more popular networking schemes
available today. By far, there are more customized networking
schemes used than listed. Consult your local packet network guru
for specific network information.
3.1 Are there any other protocols in use other than AX.25?
AX.25 is considered the defacto standard protocol for amateur
radio use and is even recognized by many countries as a legal
operation mode. However, there are other standards. TCP/IP is
used in some areas for amateur radio. Also, some networking
protocols use other packet formats than AX.25.
Often, special packet radio protocols are encapsulated within
AX.25 packet frames. This is done to insure compliance with
regulations requiring packet radio transmissions to be in the
form of AX.25. However, details of AX.25 encapsulation rules
vary from country to country.
3.2 What is TCP/IP?
TCP/IP stands for Transmission Control Protocol/Internet
Protocol. This is commonly used over the Internet wired computer
network. The TCP/IP suite contains different transmission
facilities such as FTP (File Transfer Protocol), SMTP (Simple
Mail Transport Protocol), Telnet (Remote terminal protocol), and
NNTP (Net News Transfer Protocol)
The KA9Q NOS program (also called NET) is the most commonly used
version of TCP/IP in packet radio. NOS originally was written
for the PC compatible. However, NOS has been ported to many
different computers such as the Amiga, Macintosh, Unix, and
others. Smaller computers like the Commodore 64 and the Timex-
Sinclar do not currently have version of NOS available.
3.3 Networking Schemes
What are some of those other networking schemes?
During the early days of amateur packet radio, it became apparent
that a packet network was needed. To this end, the following
packet network schemes where created.
Digipeaters
The first networking scheme with packet radio was Digipeaters.
Digipeaters would simply look at a packet, and if it's call was
in the digipeater field, it would resend the packet. Digipeaters
allow the extension of range of a transmitter by retransmitting
any packets addressed to the digipeater.
This scheme worked well with only a few people on the radio
channel. However, as packet became more popular, digipeaters
soon were clogging up the airwaves with traffic being repeated
over long distances. Also, if a packet got lost by one of the
digipeaters, the originator station would have to retransmit the
packet again, forcing every digipeater to transmit again and
causing more congestion.
KA-Nodes
Kantronics improved on the digipeater slightly and created KA-
Nodes. As with digipeaters, KA-Nodes simply repeat AX.25 frames.
However, a KA-Node acknowledges every transmission each link
instead of over the entire route. Therefore, instead of an end-
to-end acknowledgement, KA-Nodes allow for more reliable
connections because acknowledgments only carried on one link.
KA-Nodes therefore are more reliable than digipeaters, but are
not a true network. It is similar like having to wire your own
telephone network to make a phone call.
NET/ROM
NET/ROM was one of the first networking schemes to try to address
the problems with digipeaters. A user connects to a NET/ROM as
if connecting to any other packet station. From there, he can
issue the NET/ROM commands to instruct it to connect to another
user locally or connect to another NET/ROM. This connect then
connect again means that to a user's TNC, you are connected to a
local station only and it's transmissions does not have to be
digipeated over the entire network and risk loosing packets.
This local connection proved to be more reliable.
NET/ROM don't use all of the AX.25 protocol. Instead, they use
special AX.25 packet called Unnumbered Information (UI) packets
and then put their own special protocol on top of AX.25. This is
again used to increase efficiency of it's transmissions.
NET/ROM is a commercial firmware (software put on a chip) program
that is used as a replacement ROM in TAPR type TNC's. Other
programs are available to emulate NET/ROM. Among them are
TheNet, G8BPQ node switch, MSYS, and some versions of NET.
NET/ROM nodes, at regular intervals, transmit to other nodes
their current list of known nodes. This is good because as new
nodes come on-line, they are automatically integrated in the
network, but if band conditions such as ducting occur, often
unreachable nodes are entered into node lists. This causes the
NET/ROM routing software to choose routes to distant nodes that
are impossible. This problem requires users to develop a route
to a distant node manually defining each hop instead of using the
automatic routing feature.
ROSE
Rose is another networking protocol derived from X.25. Rose
nodes have a static list of the nodes it can reach. For a user
to use a ROSE switch, he issues a connect with the destination
station and in the digipeater field places the call of the local
rose switch and the distant rose switch the destination station
can hear. Other then that, the network is completely transparent
to the user.
The static routing tables ROSE uses ensures that packet routing
does not use unreliable links such as NET/ROM suffers from.
However, ROSE suffers from it's inability to change it's routing
table as new nodes come on line. The operator must manually
change every routing table, thus ROSE networks require greater
maintenance times.
3.4 BBS message transfer
Many of the BBS programs used in packet radio allow for mail and
bulletins to be transferred over the packet radio network. The
BBS's use a special forwarding protocol developed originally by
Hank Oredsen, W0RLI.
Besides full service BBS's, many TNC makers have developed
Personal BBS software to allow full service BBS to forward mail
directly to the amateurs TNC. This allows operators to receive
packet mail at night and avoid tying up the network during busy
hours.
- End of Amateur Packet Radio Frequently Asked Questions -
