hacking

	==Phrack Magazine==

	Volume Four, Issue Forty-Four, File 9 of 27

	****************************************************************************

	The Amateur Radio Packet Network
	by Larry Kollar, KC4WZK

	... As a low-orbit satellite comes into range, Jim's system
	automatically goes into action. The computer downloads the last
	half of an image taken by the satellite's CCD camera, the first
	half having been taken on the previous pass. That done, the
	computer gets a list of new files on the satellite's BBS and
	downloads Jim's email...

	It's legal.

	... Her mother is on the phone, but Rhonda accesses the local
	BBS by radio. She logs in to read postings from a world-wide
	network and her email from a penpal in Great Britain...

	It's not Internet.

	... 11:30 p.m., and the local conference node is jumping. Two
	people were trying to work out a computer problem, when the
	local expert checked in with some ideas. Before long, three
	more people checked in and a freewheeling discussion got under
	way...

	It's happening now.

	While the Internet has been growing fast and with great hoopla, amateur radio
	operators (or "hams") around the world have been quietly building a network of
	their own -- the Amateur Radio Packet Network. Like Internet, the packet
	network has a large TCP/IP component and is available to anyone who can get
	access. Unlike Internet, getting access is very easy for nearly anyone who
	already has a ham license.

	The packet network is rather loosely organized, and is built and maintained by
	volunteer work. It's basic building block is the LAN (actually a MAN, or Metro
	Area Network, but terminology is never 100% accurate), which are coordinated by
	local or regional clubs. A LAN occupies a specific radio frequency (or channel,
	if you want to be crude about it :-), usually VHF or UHF, within a given area.
	Individuals and the regional organizations provide links between LANs for
	communications outside the local area.

	LAN operations work much like Ethernet -- your radio waits for the frequency to
	be clear, then transmits a packet. This allows several connections to run at
	once. Most packet systems can themselves maintain up to 10 simultaneous
	connections, but this feature is used only rarely.

	----------------------
	Packet Radio Equipment
	----------------------

	Hams to want to use packet radio need three pieces of equipment:

	- A radio (of course). Most LANs are found on the 2-meter band (144-148 MHz,
	with packet concentrated around 145.0 MHz and 145.6 MHz. Many hams dedicate
	older crystal-controlled commercial or ham radios to packet work.

	- A TNC (Terminal Node Controller). This is an intelligent box that contains a
	packet modem much like the guts of a landline (telephone) modem, and a micro-
	computer that handles the network interface. Other alternatives are
	available, including a dumb radio modem that plugs into a PC (software on the
	PC then handles the network interface), and multimode controllers that can
	handle other digital communication methods popular among hams. However, most
	hams use TNCs since they are cheap (just over $100) and readily available.

	- A terminal, or a PC running a terminal or packet program. Since TNCs are
	smart devices, a simple terminal or terminal emulator is all that's required:
	if it has a keyboard, a display, and an RS-232 port, you can use it with a
	TNC. However, many features (multiple connections, for example) are more
	useful if you have a computer running special packet software.

	Currently, most hams use 1200 baud on 2 meters. This is the lowest (very)
	common denominator in packet radio. However, large urban areas are starting
	many new LANs in the 420-450 MHz amateur band; most of these use 9600 baud as
	a minimum. As time goes on, and packet radio becomes more popular, 9600 baud
	will become the entry level.

	When many inter-LAN links use 56K baud, and some go as high as 2M baud, why
	are the vast majority of hams still using 1200 baud? Part of the answer is
	technical: to get reliable performance at better than 2400 baud, you have to
	tap into the guts of the radio, bypassing the audio stages for both transmit
	and receive. The other part is social: everybody else is using 1200 baud,
	why spend extra money for stuff you can't use? The technical problem has been
	solved -- you can buy "data radios" in kits and pre-built models that come with
	the audio bypasses already in place -- but it will take a few years or a good
	reason for hams to abandon their old gear and move up.

	--------------------
	Local Communications
	--------------------

	There is lots of local action to be found on the LANs. People and clubs run
	BBSes, conference nodes, and many personal mailboxes. Most BBSes are set up so
	they can send email and specified bulletins (equivalent to Usenet newsgroup
	articles) to personal mailboxes during late night hours when usage is light. A
	ham using this setup simply accesses his personal mailbox to get his feed for
	the day, not worrying about noise and propagation delays.

	In general, a ham who wants to add a component to a LAN just puts it up and
	advertises it on the local BBSes. For example, a friend in my area recently
	set up a "QUOTES" BBS dedicated to sharing quotes and funny stories. Perhaps by
	time this issue of Phrack is published, I will have a Xenix system available for
	logins over the air.

	In most areas, the local networks use AX.25 (a subset of X.25 designed by hams
	especially for packet radio), although TCP/IP is getting popular in some places.
	I'll talk more about this later.


	-----------------------
	Linking It All Together
	-----------------------

	A single LAN is useful, but the REAL power comes from hooking them together.
	Linking LANs into a wide-area network gives the Internet its power; so it goes
	with the packet network. With inter-LAN links, we can send email nationwide
	(and to many foreign countries), post articles (bulletins) for general reading,
	and even make distant keyboard-to-keyboard contacts -- with some limitations.

	So how is it done? Since many metro areas support a dozen or more LANs, these
	are usually linked together with high-speed UHF equipment using TCP/IP. An
	Atlanta-based group called GRAPES has developed a 56K bps system; some
	experimental links in the microwave bands run as fast as 2 MEGA bps!

	For long-haul links, many areas rely on HF (shortwave) frequencies. Since the
	FCC limits HF packet to 300 baud (yes, you read that right -- 300 baud), and the
	HF frequencies are often very noisy, this is a slow and painful process. The
	amazing thing is not how slow it is, but that it works at all!

	For this reason, many forward-looking hams are turning to packet satellites for
	long-haul links. The advantages include relatively quiet frequencies, 9600 baud
	data rates, and predictability; the major disadvantage is that there are simply
	not enough satellites to handle all the traffic that needs to be handled -- yet.
	I'll talk more about packet satellites later.

	-------------------------------
	AX.25, TCP/IP, and All the Rest
	-------------------------------

	The packet network grew from a handful of different experiments with radio
	networking, which has left us with several networking protocols. Far and away
	the most popular protocol is AX.25, which is built into thousands and thousands
	of TNCs and other packet controllers. AX.25, as implemented in most ham gear,
	offers up to 10 simultaneous connections and the ability to "digipeat" packets.
	Digipeating (DIGItal rePEATING) is one way to extend the range of a packet
	station -- if you can't reach the station you want to talk with directly, you
	can often digipeat through a station between you and the other person. One
	problem is that you have to manually construct a route each time you want to
	contact a distant station. The other problem is that the send-acknowledge
	sequence has to run all the way across the link. Digipeating through more than
	one or two stations is a good way to annoy other LAN users, and unreliable to
	boot. The connection works as follows:

	---send---\ /-------->
	station1 digi station2
	<---------/ \-- ack --

	One popular improvement on the digipeater is the K-node, developed by Kantronics
	(a vendor of packet equipment). The K-node establishes two links -- one between
	you and the node, the other between the node and the other station. Each link
	has its own send-acknowledge loop, so a problem in one leg of the connection
	doesn't require re-sending packets through the entire end-to-end connection --
	only through the leg where the packet got garbled. This connection works as
	follows:

	---send---\ /--send-->
	station1 K-node station2
	<--ack----/ \-- ack --

	The K-node shares one disadvantage with the digipeater -- you still have to
	manually construct your own connection. This is where the higher-level
	protocols come in.

	I've already mentioned TCP/IP. Yes, we have it. The 44...* network is
	assigned exclusively to amateur packet operations. The network name is
	"ampr.org." Since TNCs do not have TCP/IP in ROM, some kind of personal
	computer is required. Most of them work -- PCs, Macs, Amigas, Ataris all have
	TCP/IP networking software. If you've ever used the free KA9Q NOS software (or
	one of its derivatives), you have software that was developed by hams for hams.
	TCP/IP lets amateurs create all sorts of interesting experiments, such as
	setting up "wormholes" through the Internet to relay traffic between distant
	LANs. Some parts of the country have Internet/packet email access as well.

	There are other "smart" networking protocols in wide use. NET/ROM is one highly
	popular protocol. Each NET/ROM node keeps a table of nodes heard and how to
	reach each one, eliminating the hassles of manual routing. One problem with
	NET/ROM is that during band openings, VHF and UHF signals can carry for hundreds
	of miles beyond their normal range. ("Line of sight?" Yeah right -- a friend
	of mine in north Georgia has made contacts with people as far away as Lincoln,
	Nebraska on 2 meters using the stuff he carries around in his truck.) After a
	band opening, NET/ROM nodes find themselves stuffed with faraway nodes that
	they can't hear anymore.

	The phreakers in the audience may find ROSE interesting. ROSE bases addresses
	on the NANP area code/prefix scheme. If a person uses ROSE, and you know her
	call sign and phone number, you contact her at the address "<call> VIA AAAPPP."
	Unfortunately, ROSE does not have the widespread use necessary to make it a
	nationwide network.

	There are several other networking protocols in use, such as TheNet and a few
	others. However, I expect TCP/IP to replace most if not all competing protocols
	in a few years.

	-----------------
	Packet Satellites
	-----------------

	Here's something you won't see on Internet. Maybe some of Internet's traffic
	goes over satellites, but direct contact?

	Since 1959, amateurs have launched nearly 30 satellites into orbit. Nearly
	20 of these are still in service -- and most of them are dedicated at least
	part-time to packet operation.

	>From a user's standpoint, there are two different types of packet satellite --
	one type using 1200 bps FSK (frequency-shift keying) and the other using 9600
	bps FM. The current population is split, with about a half dozen of each type.
	Most packet satellites, or pacsats, are based on a design from University of
	Surrey in Great Britain -- they're small and lightweight, keeping launch costs
	to a minimum. Pacsats are always launched as secondary payloads, and often
	ride as ballast to reduce launch costs even further.

	Many pacsats have on-board CCD cameras that can take pictures of Earth or space,
	and make the pictures available for downloading from the on-board BBS. Other
	pacsats carry equipment that allow them to be switched into a transponder mode,
	such as the Japanese FujiSat that carries SSB and CW (Morse code) contacts on
	Wednesdays, or can even be converted into an FM repeater such as AO-21.

	Some special software has been developed to make the most of the limited
	bandwidth. For example, pictures can take more time to download than is
	available during a single pass (normally 10-20 minutes), especially if other
	users are sending and downloading other files at the same time. The software,
	called PB, lets you download and upload as much of a file as possible during
	one pass, then gets the rest of the file on subsequent passes. Other software
	lets you automate the entire process, so you can get new files as they arrive
	without having to get up early for that 4 a.m. pass. PB also lets you download
	files by listening in -- if another person is downloading the file you want, you
	can simply listen to the downlink and let PB construct the file for you. This
	is a good way to save bandwidth; if two people want the same file, only one of
	them has to actually download it. If there are holes in the file, you can fill
	them in later.

	--------------------------------
	Getting an Amateur Radio License
	--------------------------------

	There are five grades of amateur radio licenses in the U.S.; from lowest to
	highest, they are Novice, Technician General, Advanced, and Extra. Each grade
	of license has a test on theory and regulations, with a Morse code "element"
	required for several of them.

	The good news is that 99% of what packet radio has to offer is available to the
	Technician. The better news is that the Technician license, as of January
	1991, no longer requires you to learn Morse code. The "codeless Tech" has
	brought a great deal of new blood into ham radio, including many hackers and
	mainstream computer people.

	Study guides are available from Radio Shack and the American Radio Relay League
	(ARRL); the ARRL's guides are the better of the two, in my opinion. You can get
	ARRL study guides at most ham radio stores or directly from the ARRL. If you
	want to get a codeless Technician license, you'll need the Novice and the
	Technician study guides. The material isn't very hard to learn; anyone who can
	navigate the guts of Ma Bell will have no trouble with the Novice or Technician
	exams. :-)

	The ARRL can also provide you with a free schedule of exams in your area. The
	FCC some years ago turned over all testing to accredited amateur groups, so you
	should be able to find an exam at a time and place convenient to you. Many
	other ARRL services are available through an Internet mail server; send mail
	to info-server@arrl.org containing the line "send index" in the body of your
	message.

	If there's any bad news, it's that a group of diehards can't stand the idea of
	a code-free ham license. Some of these folks will go out of the way to hassle
	code-free hams. Fortunately, most of them are afraid of computers and don't
	do packet. Other things to watch out for -- the FCC frowns on profanity,
	intentional jamming, and encrypted data sent over the air. A small price to
	pay, in my opinion, for the opportunity to build and explore a worldwide network
	without the Secret Service breathing down your neck.

	-- end --