The Packet Radio Handbook by Buck Rogers K4AB

The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” A Packet Primer for the new Packeteer __ Page 0
Two Packet Radio Books In One Cover
Section I
A Primer for the
Packet Radio
BEGINNER
Section II
A HANDBOOK for the ADVANCED
Packet Radio
System Node Operator
by
Buck Rogers K4ABT
E-Mail k4abt@packetradio.com PacketRadio Editor, CQ Magazine
PacketRadio Networking
http://www.
packetradio.com
Section 1; Packet Radio “The Basics” Section 2; Revised 2009 X1J4 System Node Operator’s Handbook
Copyright 1991-2012, G E Rogers Sr K4ABT and BUXCOMM Inc.,
Section 1; Packet Radio “The Basics” A Packet Primer for the new Packeteer __ Page 2
About The Author
(Semper Fidelis)
Proud to claim the title of former United States Marine, the Corps’ own motto,
Semper Fidelis, serves as a good description of G. E. “Buck” Rogers’ own attitude
toward family, work, and humanitarian service… ”always faithful.” Married to Jean
Ann (Dyson) Rogers for over 41 years, Buck and Jean Ann (WB4EDZ) have two children,
Glynn E. Jr.(WB4RHO), and Janice Evelyn (Rogers) Mata, and six grandchildren.
In addition to spending time with his family Buck provides technical support and
inspiration for the Southeastern Emergency Digital Association Networks (SEDAN), a
humanitarian organization comprised of licensed radio amateurs dedicated to helping
others in times of disaster. In fact, it was Buck’s youthful interest in Ham radio
that eventually led to his present career position as Senior Systems Engineer for
Ericsson Communications.
Buck is a recognized world-class expert in the field of RF communications,
having been instrumental in the design and implementation of the U.S. Air Force
Local Area Network, Wide Area Network, and Global Information Networks (LAN, WAN &
GIN). His credentials in other fields of RF communications also include terrestrial
microwave systems design, television and radio broadcast station design, and Public
Service Specialized Communications systems design. His communications consulting
travels have taken him throughout the United States, Europe, Asia and other
countries around the world.
Buck, K4ABT, is highly respected in the Amateur Radio community both as a
pioneer of Packet Radio and noted author, having published twelve books and written
many feature articles for the leading Amateur radio, commercial and trade
publications. He is Packet Radio Editor of CQ MAGAZINE and every month authors the
“PACKET USERS NOTEBOOK,” a popular column in CQ MAGAZINE distributed world-wide
and translated into several languages.
Buck is a licensed radio Amateur for over 50 years and holds the “lifetime”
Commercial FCC First Class license, now called the General Class Commercial license.
He conducts forums and seminars on packet radio and digital communications, and is
the author of twelve books, some of which include:
· Packet Radio Basics: The Beginners Guidebook
· Packet Radio X1J4 System Node Operator’s Handbook
· Packet Radio Operator’s Handbook (The PRO )
· Packet Radio Operators Manual (PROM, from CQ Publications)
· Packet Radio: General Information Handbook
· The Advanced Packet Radio Handbook
Buck also grows the world’s best backyard tomatoes.
Richard Card, KD4JKX
President, Southeastern Emergency Digital Association Networks (SEDAN)
July 1999
Reproduction or use, without express permission, of editorial or pictorial content, in any manner, is prohibited.
While every precaution has been taken in the preparation of this handbook, the author and publisher assume no
responsibility for errors or omissions. Neither is any liability assumed for damages resulting from the use of the
information contained herein.
Copyright(c) 1992, 1995, 1996, 1997, 1998-99
Section 1; Packet Radio “The Basics” A Packet Primer for the new Packeteer __ Page 3
All rights reserved
The information in this document has been checked and is believed to be entirely reliable. However, no
responsibility is assumed for inaccuracies. Portions of this handbook are excerpted, with permission, from the X1J4
original documents by X-1J4 author Dave Roberts and Fiona and Neville Pattison.
Credits & trademarks, Ô & ©
· APPLEÔ & Apple Macintosh trademarks of Apple computers Inc.
· ERICSSON are © & Ô of ERICSSON Communications & ERICSSON Private Radio Systems
· EDACSÔ is trademark of ERICSSON, Inc,.
· IBMÔ and IBM PC are trademarks of International Business Machines.
· MFJ is a trademark Ô of MFJ ENTERPRISES INC
· MULTICOM and MultiCom for Windows isÔ of MFJ ENTERPRISES INC
· NETROM is Ô & © of Software 2000
· TheNET is © Nord><Link Packet Group of Germany
· TAPRÔ Tucson Amateur Packet Radio is a non-profit research group dedicated to amateur digital
communications.
· TRS-80 and CoCo are Ô of Tandy/Radio Shack Corp.
· WindowsÔ, Windows 95Ô, Windows NTÔ and MS/DOS are © of Microsoft Inc,.
· X1J-4 is the latest version of theNet and is © title applied by Dave Roberts G8KBB.
This handbook is dedicated to the people I love, and to the
hobby and profession that I enjoy.
G. E. Rogers Sr
“Buck” K4ABT
Section 1; Packet Radio “The Basics” A Packet Primer for the new Packeteer __ Page 4
TABLE of CONTENTS
About the Author Page 2
Credits and Trademarks Page 3
An Introduction to PACKET RADIO Page 5
Section I; The PACKET RADIO BEGINNER’S GUIDEBOOK
CHAPTER 1 Packet Radio “The Easy Way !” Page 6
“BUXTERM”… a Packet terminal program and it’s FREE! Page 7
And… there’s more information at:….. www.PacketRadio.com
A PacketRadio FREQUENCY GUIDE Page 9
CHAPTER 2 LEARNING ABOUT PACKET CONTROLLERS Page 10
CHAPTER 3 ANTENNAS FOR PACKETRADIO Page 12
CHAPTER 4 USING THE PACKET BBS: Page 15
Section II; The 2008 X-1J4 System Node Operator’s HANDBOOK
Chapter 5 Section II WHAT IS A PACKET NODE? Page 18
Chapter 6 Section II - FEATURES OF THE X-1J4+ NODE Page 19
Defining a few of the X-1J4 features Page 20
Chapter 7 Section II Understanding theNET X-1J 4 Node Page 22
Chapter 8 Section II Using the advanced features of the X1J4 Node Page 25
Chapter 9 Section II Constructing, Installing, and Configuring TheNET X1J/4 NODES Page 27
Chapter 10 Section II DUAL AND MULTI-FREQUENCY NODE OPERATION: Page 28
Chapter 11 Section II MOST FREQUENTLY USED SysOp & User COMMANDS: Page 30
Chapter 12 Section II SYSOP VALIDATION: (HANDLING THE PASSWORD) Page 31
CORRECTING MISTAKES IN TEXT ENTRIES to X-1J4+ Page 31
Chapter 13 Section II HOST MODE: Page 32
Chapter 14 Section II ROUTE QUALITY ANALYSIS: Page 34
Chapter 15 Section II DIGIPEATING AND HOST INTERFACE Page 35
Chapter 16 Section II GATEWAY INTERFACING & SETUP: Page 36
Chapter 17 Section II X-1J4+ PARAMETERS; DEFAULTS & RANGES Page 39
TheNET PARAMETERS; EXPLANATIONS Page 40
Chapter 18 Section II X1J4+ MODE COMMANDS AND DEFINITIONS Page 43
APPENDIX "A" FINAL NODE “CHECKLIST:” Page 44
APPENDIX "B" LOCKING ROUTES AND SETTING “FIXED” NODE PATHS: Page 45
APPENDIX “C” The X1J4/Neville Pattinson/MFJ-52B Deviation meter Page 48
ADC installation and SCALING FACTORS FOR THE MFJ-52B Page 49
APPENDIX "D" ACL Access Connect Limiting “Its use and abuse” Page 51
ILLUSTRATION MODIFYING THE MFJ-1270 (no suffix) for gateway operation Page 52
ILLUSTRATION MODIFYING THE MFJ-1270”B” for X-1J4 MFJ-52B installationPage 53
ILLUSTRATION MODIFYING THE MFJ-1270”B” for X-1J4 as an X-1J4 Node Page 54
ILLUSTRATION MODIFYING THE MFJ-1270”C” REV 10 for X-1J4 Node service Page 55
ILLUSTRATION MODIFYING THE MFJ-1270”C” REV 11 for X-1J4 Node service Page 56
Supporting instructions & procedures for MFJ-1270C “REV 11” Page 57
Section 1; Packet Radio “The Basics” A Packet Primer for the new Packeteer __ Page 5
AN INTRODUCTION TO
PACKET RADIO:
by
Buck Rogers K4ABT
PACKET RADIO IS:
ommunications between computers using radio (RF) as the medium rather than wires or solid mediums. Your
personal computer in your ham shack coupled to your VHF or UHF transceiver via a terminal node controller (TNC) is
the makeup of the Packet Radio station. Computer terminal programs enable computers to send and receive Ax.25
Packet along with other well know digital modes such as CW and RTTY. The mode we are most interested in it called
“Packet Radio.”
Packet Radio is faster and is completely error-free as compared to CW and RTTY. This mode of data communications
allows us to deliver ASCII text, binary data, and even digital video via this high speed and error-free communications
medium.
One of the many benefits of using Packet Radio is that it preserves spectrum by allowing several stations can share one
frequency at the same time. By using the X-1J4 network node base described later in this book, you will discover other
ways that Packet radio can link your State, Country, or even the World into one massive network. One of the elements or
off-springs of Packet communications is the internet. Much like Packet radio, the internet uses every conceivable type or
kind of medium to transverse from point A to destination B. The internet uses longer packets with a protocol based on
Transmission Control Protocol (TCP) with Internet Protocol (IP) addressing.
THE TERMINAL NODE CONTROLLER (TNC):
By now you have heard the phrase, “terminal node controller” or “TNC” several times. The terminal node controller
(TNC) performs as an interface between the computer and the transceiver. The TNC combines a modem and a packet
assembler/disassembler that accepts information from your computer and sends received data to your computer. The TNC
(prior to 1983 it was called a “PAD” or packet assembler/disassembler) breaks data into “packets.” These packets are
normally 128 letters or characters in length. In our Packet TNC we have the option to increase this packet length up to 255
characters in length. The TNC command that allows us to make this change is called “PacLen.”
Once the TNC has received the data from your computer, it then breaks it into packets about 100 characters long and
combines additional (bytes) information to the outgoing data. The added bytes include the destination addressing, errorchecking,
and frame control information. Address and destination information that is added in by the TNC includes the
callsign of the target station and the callsign of the station sending the packet (data). This same frame or data packet will
also contain the path or nodes that is used between the two connected stations. The forward error-checking intelligence
within the AX.25 Packet frame enables the target station to ascertain that the was received without any errors. If errors
were received, the receiving station sends a non-acknowledge (NACK) Packet indicating to the sending station that it must
repeat the Packet again or until the Packet is received “error free.” Once the Packet is received error-free, the receiving
station will send an “ACKnowledge” packet to indicate that the data was received as sent.
DIGIPEATERS & NODES:
Any packet radio station can act as a digipeater. A digipeater is a “store-and-forward” Packet station. Most TNC's are
setup to digipeat automatically without any effort on the part of the station being used as a digipeater. To reach a distant
station, we connect to any remote node that is in range of our station. From this point on, we use the remote node as if we
have a long cable between our computer and the remote node. Once connected to the remote node we can instruct the node
to connect our station to a distant Packet station. The node will “ACKnowledge” packets between our station and the target
or destination station. The node is also a “store-and-forward” device that may be located atop a mountain or tall structure
that enables it to hear Packet stations that are beyond our stations reach. This handbook has a complete section dedicated to
the construction, configuration, operation, and use of nodes. Read on as you are about to discover how much fun and
enjoyment Packet Radio
c
Section 1; Packet Radio “The Basics” A Packet Primer for the new Packeteer __ Page 6
Chapter One
Packet Radio 2008 “The Easy Way !”
PACKET RADIO:
The Easy Way !©
by Buck Rogers K4ABT
© 1986 Updated; 1990, 1997
When I first wrote “PACKET RADIO: The Easy
Way!” in 1986, I felt that somehow the new or
prospective Packeteer would not feel comfortable with
an attempt at setting up his or her Packet station
without some means of tutorial. That was when I
decided to write this tutorial. I had to give the ham
who might be willing to give Packet Radio a try, a
head start by taking them around the pitfalls that I
had experienced when I set up my first Packet station.
When I began my Packet Radio hobby, there were no
neighbor Packeteers, Packet books or tutorials that
might provide guidance for a beginning Packeteer.
Here then, is a brief and easy to understand guide for
the first time Packet Radio operator.
WHAT DO YOU NEED TO BEGIN OPERATING
PACKET?
The equipment needed to get on the air is a VHF
transceiver, a computer or terminal, and a terminal node
controller (TNC). There is packet activity on HF, but
VHF is the best place to start out in Packet Radio. The
TNC contains a modem similar to the modem used to
connect your computer to the phone lines, except that it
also contains special firmware especially designed for
Packet radio.
When you take the TNC out of the carton, most of the
time you'll find cables are provided with the TNC
connectors supplied. The other end of the cables that
attach to the transceiver and computer are not supplied.
The reason is that the TNC manufacturer has no idea
what kind of radio you might be connecting the TNC to.
The burden is on the user to purchase the correct
connector for the transceiver and computer that will be
used with the TNC. Determine the kind of microphone,
speaker jack, and computer serial comport connectors
that you're going to use. In some cases the TNC
manufacturer furnishes only the connector for the TNC.
This means that you must also furnish the cable that
connects the TNC to your computer or terminal. In most
cases, a 25 pin RS-232 serial cable is used between the
TNC and computer. The later models employ a 9 pin
serial connector, thus you will need a 9 pin
connector/cable.
This may vary depending on the type and make of
computer terminal being used. Check the serial comport
of your computer to be sure of the type connector that you
will need. DO THIS BEFORE GOING TO THE PARTS
SUPPLY HOUSE!
In most cases the computer will have either a 9 pin male
connector, or a 25 pin male connector as the RS-232
serial comport. If this is the case, you will have to supply
the female connector for the computer end of the cable.
Be sure to note the number of pins on the
computer/terminal connector.
The operating manuals supplied with most TNC provide
adequate directions for use of various computers. Look
for the computer to terminal node controller (TNC)
interface section in the TNC manual. In most
applications the cable for your TNC to computer may be
purchased “ready-made” for many computer vendors.
When all else fails read the manual and set up procedures
for your TNC very carefully. The manual that is supplied
with your TNC may have information that is specific to
the personality of your TNC.
LADIES AND GENTLEMEN, START YOUR
.......tee N cee’s
Once you have everything wired and connected together,
turn on the computer, load a terminal program. There
are lots of terminal programs available for use with
Packet radio.
If you do not have a Packet terminal program, then send
an MS/DOS formatted disk and a self addressed and
postage paid return mailer to me and I will provide you
with a copy of BUXTERM.EXE along with the
BUXTERM manual.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section 1; Packet Radio “The Basics” A Packet Primer for the new Packeteer __ Page 0
IT IS FREE ! There is no “catch”, it is FREE! You
supply the disk, mailer, and return postage.
Mail TO: BuxTerm
115 Luenburg Drive
Evington, Virginia 24550
You can also download BUXTERM from one of my web
sites at; www.PacketRadio.com
Next we switch on the VHF transceiver and turn the
volume up a quarter turn or just above the "9:00 o'clock
position." Make sure the squelch is not set too tight.
The squelch should be set to a position where the
transceiver is quite. The squelch is set in a similar
manner that you would use for voice operation.
There are two communication speeds that are used in
Packet Radio. It is necessary that each new Packeteer be
aware of the meaning of each speed, and the relationship
to his/her Packet station. The first speed is the terminal
to TNC baudrate. The second speed is the “ON-AIR” or
radio (VHF) baudrate.
Since we are about to begin operating in the VHF region
we will begin with an on-air baudrate of 1200 baud’s.
ABAUD refers to the terminal to TNC, and HBAUD
refers to the RADIO or ON-AIR baudrate. Most
computer and TNCs will operate at an Abaud of 9600
baud’s.
The following figure will give you an idea of two
communication functions that we are discussing.
1 2 3
1. Computer or Dumb Terminal
2. Packet Radio Terminal Node Controller
(TNC)
3. VHF or UHF Transceiver
NOW LET'S BEGIN HAVING FUN:
If you’ve followed the setup procedures outlined in the
manual that comes with your TNC, then you are ready to
take the plunge into the wonderful world of operating
Packet.
Verify that all control, signal and ground wires (PTT,
RECEIVE, AFSK, and SIGNAL GROUND) are
connected to the correct connector pins.
TURN ON THE TNC!
When you first turn on the TNC you may see garbled text
on the screen. This is usually because the terminal to
TNC baudrate is not set to the same parameters. Some
TNCs will do a "search" mode to find the setting that you
have your terminal program set to/for. If at first you see
garbage on the screen then clear text begins to appear,
you should follow the instructions that appear on the
screen. If you are unable to establish communications
with the TNC, then review the TNC manual for further
instructions. The baud rate of the TNC has to match the
baud rate used by your computer terminal program and is
easily adjusted. When the terminal to TNC parameters
are correct, a message will appear on the screen showing
the TNC manufacturer's name, firmware version, and
date of EPROM program.
Perform a "control C" (press Ctrl and the letter C at the
same time); this places the TNC into command (cmd:)
mode.
This is where all commands are issued from you to the
TNC. Any command that is typed while in the "cmd:
mode is received by the TNC as a direct order.
Once in the command mode, you can press the [Enter]
key and each time you press the [Enter] key a "cmd:"
prompt should appear on the screen. This is an
indication that you have control (command) of the TNC.
The next step will be to set our callsign into the TNC.
To put our call sign into the TNC, at the cmd: prompt,
we type and [Enter] the following:
MY (my call) or (your call)
I send my call sign to my TNC in the following manner.
Type and [Enter] to the keyboard/TNC: (the [Enter]
simply means I pressed the Enter key).
MY K4ABT [Enter]
You may now test the TNC to see if your call sign is
indeed set into the TNC. To do so, type:
MY [Enter] and the TNC should respond with:
MYCALL K4ABT
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section 1; Packet Radio “The Basics” A Packet Primer for the new Packeteer __ Page 0
This lets us know that the computer and TNC are
communicating.
Now that you have entered your call sign as we have just
described, followed by a carriage return, (CR or [Enter],
we are ready to set other commands into our TNC. If
there is no response when you type MY, then try typing:
ECHO ON [Enter]
The :cmd:" should appear on the screen again, with a
message similar to the following:
ECHO was OFF
NOTE; If you are seeing double letters (i.e.; MMYY
CCAALLLL) displayed when you type, this indicates that
the ECHO command should be turned OFF. Type the
following :
ECHO OFF
The TNC may respond with:
ECHO was ON
Here are some other commands that we should make
active; Type them in as I have shown them below:
MON ON
MCOM ON
MCON OFF
MRPT ON
If you’ve wired the RS-232 interface cable using the
RTS, CTS, Txd, Rxd, and Signal Ground leads, then set
the XFLO command OFF. If you did NOT use the
RTS, and CTS signals, then make sure the XFLO
command is ON.
THE MOMENT OF TRUTH:
The most used frequency for VHF Packet Radio operation
is 145.010 MHz; However there are many other
frequencies that are set aside for Packet Radio use. The
SouthEastern Digital Association Networks (SEDAN) is
operating at 145.770 Mhz..
The following is a list of other VHF, and UHF Packet Radio
simplex frequencies (In Mhz):
144.91, 144.93, 144.95, 144.97, 144.99, 145.01, 145.03, 145.05,
145.07, 145.09, 145.51, 145.53, 145.55, 145.57, 145.59, 145.61,
145.63, 145.65, 145.67, 145.69, 145.71, 145.73, 145.75, 145.770.
Included in the ARRL future band plans are several
simplex (64 kB), 100 kHz backbone frequencies within
the 219 > 220 Mhz UHF band, (FCC approved 16 March
1995 with restrictions, see CQ Magazine PUN June
1995)
Below are a few frequencies that are set aside for Packet Radio use
in the 420 > 450 Mhz band:
430.050, 430.150, 430.250, 430.350, 430.450, 430.550, 430.650,
430.850, 430.950, 440.975, 441.000, 441.025, 441.050, 441.075,
446.500.
As I mentioned earlier, make sure the MONITOR
command is ON, then watch the screen. If you have
tuned to one of the Packet frequencies mentioned above
and you are not yet seeing data appear on the screen, then
try the SEDAN 1200 baud access Packet frequency of
145.770.
When all else fails call a Packet friend and ask them to
connect to your call. If you are using an *SSID of your
call, be sure to include this in the information that you
give the friend. While you are about it, ask if he/she uses
an SSID.
AWW SSID !
Now that I have you wondering; "What is an SSID?"
Here is a brief explanation for the “Secondary Station
IDentification” (SSID). In Packet Radio you can have
up to 15 Secondary Station IDentifiers (SSID's), an
example is K4ABT-1 through K4ABT-15. K4ABT
without an SSID extension, is considered the 0 (zero)
SSID, thus we could have sixteen different stations/calls
on the air at the same time using our single call sign.
That's where the numbers in the call sign come into play.
The added dash numbers (-1 etc...) numbers are used to
distinguish the various station(s) or node(s).
To connect to a station or node which uses an SSID, it is
important that we know what the SSID is before
attempting a connect to that station. To try connecting to
a station or node without having the appropriate SSID
included in the connect sequence would be like trying to
place a long-distance telephone call without using an
area code. A crude analogy, but you get my drift.
You are about to embark upon the most fun filled facet of
Ham Radio. Give it a try.
Section 1; Packet Radio “The Basics” A Packet Primer for the new Packeteer __ Page 9
LET’S BEGIN:
This is where you will find this handbook to be helpful.
I’ve written this handbook to serve as a guide to get you
started in Packet Radio. After you have your station
assembled, and working, you may wish to learn about the
more advanced levels of Packet operating.
There are books that provide detailed information for the
advanced levels of Packet operating and projects for the
more advanced levels of operating. Books for the
advanced Packet operator are:
1) PACKET RADIO OPERATOR'S
HANDBOOK (MFJ Publications)
2) PACKET RADIO OPERATOR'S
MANUAL (CQ Publications)
Be sure to visit the PacketRadio Networks Home page(s)
at: http: //www.packetradio.com and at:
http: //www.packetradio.org
Advanced levels of Packet include transmitting and
receiving high resolution color pictures (error free),
transmission of large ASCII and binary files, and how to
build and use nodes with Packet Radio.
Included in the books just mentioned, is information on
many other uses and applications for digital
communications.
YAPP is a protocol that is universally used to transfer
binary files to and from the BBS system. YAPP is not
supported in BUXTERM, however, YAPP protocol is
supported in the MFJ MULTICOM.EXE software.
NOW we are having more fun already!
73 de BucK4ABT
Section 1; Packet Radio “The Basics” A Packet Primer for the new Packeteer __ Page 10
A PacketRadio FREQUENCY GUIDE FOR THE NEW PACKET OPERATOR:
This guide is for information purposes only, and is subject to change. Some changes in future band-plans may cause
changes in the application of certain Packet frequencies. A possible change in the 219.050 to 219.950 is one example of
Packet frequency changes. The 219 Mhz band is allocated for future trunks and backbone "only." Some frequencies are
used for specific Packet modes. Note that frequencies are in MHz:
80 Meters
3.606 Packet
3.630 Packet
3.642 Packet
40 Meters
7.090-7.100 Packet
30 Meters
10.145-10.150 Packet
20 Meters
14.101-14.110 Packet
14.230 SSTV
17 Meters
18.100-18.110 Packet
15 Meters
21.099-21.105 Packet
10 Meters
28.099-28.105 Packet
28.150 -28.190 1200 baud Packet
6 Meters
50.60-51.78 Packet
50.62 Packet calling freq
51.12 9600 baud “backbone only”
2 Meters
144.910-145.090 Packet (every 20 kHz)
145.510-145.790 Packet (every 20 kHz)
144.910 through 144.950 Mhz used for DX Spotting and
NOS operations.
144.970, 144.990, 145.030, 145.070 145.530, 145.550,
145.570, 145.590, 145.610, 145.630, 145.650, 145.670,
145.690, 145.730, and 145.750 Mhz are used as Local
Area Network (LAN's) and often ported into high-speed
backbones and trunks.
145.010, & 145.050 is most often used as BBS
forwarding and local BBS connects.
145.090, 145.510, & 145.710 are sometimes employed as
DX spotting nets.
145.770 Nationwide Keyboard to keyboard and
emergency Packet communications only. Some areas
use 145.770 Mhz for emergency communications in
addition to keyboard to keyboard communications.
In some east coast areas 144.390 Mhz is used with
Automatic Packet Reporting Systems (APRS), and as a
DXCluster or DX spotting network frequency.
222 MHz
223.52-223.64 Packet
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section 1; Packet Radio “The Basics” A Packet Primer for the new Packeteer __ Page 0
Chapter Two
LEARNING ABOUT PACKET CONTROLLERS
The TERMINAL NODE CONTROLLER (TNC)
By now you have heard the phrase, “terminal node
controller” or “TNC” several times. The terminal node
controller (TNC) performs as an interface between the
computer and the transceiver. The TNC combines a
modem and a packet assembler-disassembler (PAD), that
accepts information from your computer and sends
received data to your computer.
The TNC (prior to 1983 it was called a “PAD” or packet
assembler/disassembler) that breaks data into “packets.”
Since 1983, the “PAD” has become known as the “tink”
or TNC.
Packets are normally 128 letters or characters in length.
In our Packet TNC we have the option to increase this
packet length up to 255 characters in length. The TNC
command that allows us to make this change is called
“PacLen.”
Once the TNC has received the data from your computer,
it then breaks it into packets about 100 characters long
and combines additional (bytes) information to the
outgoing data. The added bytes include the destination
addressing, error-checking, and frame control
information. Address and destination information that is
added in by the TNC includes the callsign of the target
station and the callsign of the station sending the packet
(data).
THE ALL-MODE CONTROLLERS:
These are controllers that transmit and receive PACKET
and other digital modes, such as:
PACKET, PACTOR, AMTOR, RTTY, CW, FAX
(WeFax), Slo-Scan TV (SSTV), and NavTec. They also
offer multiple ports for VHF and HF operations. The
MFJ-1278B is one such "multimode" controller that fits
into this category. The features may differ from one
"all-mode" controller to the next, so it would be in your
best interest to investigate the options which best suit
your needs.
THE PACKET CONTROLLERS:
If you plan to operate packet only, but you wish to use
both HF and VHF packet, you may want to look for a
controller which has a tuning indicator for use on the HF
bands. The MFJ-1274B is one such Packet only
controller that operates HF and VHF Packet.
It has a Packet tuning indicator for use when operating at
HF. Most of these controllers operate both HF and VHF
Packet.
Almost all Terminal Node Controllers (TNC) operate
both HF and VHF, but to try operating HF packet without
a tuning indicator is like fishing without bait, your
chances of catching anything are, little to none.
Now if you just want to operate VHF packet, there are
numerous TNCs to fill your fancy. As of this writing,
just about every TNC now supports the "MAILBOX "
feature. This allows the user to set the MAILBOX or
PBBS command ON while the computer or terminal is
being used for other tasks, such as letter writing, and data
processing. The mailbox will receive and store messages
while you are using the computer off-line or away.
If your desire is to use the ultimate in a digital, all-mode
controller, then check into the MFJ-1278 and the
companion software terminal program, MultiCom for
Windows.
Once you’ve used this combination, the rest are paled by
comparsion.
KEYBOARD-TO-KEYBOARD CONTACTS:
The number one use of Packet radio is probably keyboard
to keyboard contacts through a Packet network. Like
other digital communications modes, Packet radio can
be used to talk to other amateurs. For those who cannot
use HF frequencies, two Packet stations can talk to each
other across long distances using a PACKET radio
network.
Section 1; Packet Radio “The Basics” A Packet Primer for the new Packeteer __ Page 12
EMERGENCY COMMUNICATIONS:
Keyboard to keyboard Packet communications is where
Packet radio excels. Packet has proven many times over
its usefulness as an emergency communications medium.
The use of Packet radio as a sky-warn or weather-watch
tool has become a standard operating proceedure.
In areas where earthquakes, hurricanes, tornadoes,
storms, flood and other natural disasters have occurred,
Packet radio has been used to relay information, requests
for food, medicines, and help from the destressed area to
the proper authorities.
In a disaster area a voice repeater may be lost due to high
winds, flood, or other causes, an emergency Packet node
or station can be setup at a moments notice. Emergency
and disaster communications can be enabled
immediately.
In some regions of the country, dedicated Packet
networks are in use specifically for this purpose. One
such network is the Southeastern Emergency Digital
Association Networks (SEDAN) that reaches from
Washington DC well into south Florida. Much of the
SEDAN covers the eastern coast of the United States and
inland as far as Alabama and Mississippi. This network
is made up of over 200 nodes and provides continuity
into all the major cities where the Red Cross emergency
operations centers are located.
When disaster relief and medical teams call for supplies
of a specific type or category and where the spelling of a
medical title is important, the printed (Packet text) word
will prevail over the spoken word. With the error-free
nature of the AX.25 Packet protocol, the message is clear
and concise.
PACKET BBS OPERATIONS:
Many cities have a PACKET Bulletin Board System
(BBS) included on their Packet local area network
(LAN). 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 user base than your
local BBS users. Private messages may also be sent to
other Packet operators, either locally or who use other
BBSs.
Most BBS's have the latest Amateur radio news bulletins
and propagation bulletins posted. Many BBS's have a
file section containing various text files full of
information on amateur radio in general.
DX PACKET SPOTTING NETWORKS:
The use of Packet radio for DX spotting has become a
tool that enables the serious DXer to make DX contacts
almost as easy as “shooting fish in a barrel.” HF
operators connect to the local DX Packet node for the
latest reports on DX. Often a user will “spot” some hot
DX and distribute the DX report real time throughout the
DX spotting network.
FILE TRANSFER (ASCII, TEXT, & BINARY) :
Using special like BUXTERM, MULTICOM, PACPRO,
YAPP and many others, amateurs can pass any binary
files to other amateurs. This may also be accomplished
using TCP/IP (NOS) communications, and other
specialized protocols.
PACKET PICTURE TRANSFER:
To add more fun to our Packet Radio hobby, we can send
and receive high resolution, color pictures via Packet
Radio. The method of transfer in many programs allow
the pictures to be transferred and while they are being
received, they are displayed on the screen in 256 or more
colors. At the same time the picture is being saved to
disk for future viewing or sending to another station.
When exchanging high resolution Packet pictures with
other Packet stations, both stations must be using the
same software (terminal program).
SATELLITE COMMUNICATIONS:
The amateur radio satellites contain microcomputers that
provide special information to amateurs. Some satellites
contain TV cameras that allow users to download images
of the earth and the stars. Others provide store and
forward Packet mailboxes that enable message transfers
over vast distances. Some satellites use AX.25, some use
special Packet protocols developed for satellite
communications. Transmissions are both AX.25 Packet
using FM transceivers, and others use Single Sideband.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section 1; Packet Radio “The Basics” A Packet Primer for the new Packeteer __ Page 0
Chapter Three
Antennas For Packet
I'm not suggesting that any digital radio user should select one antenna over another. Use whatever you have, or choose the
antenna that best favors your needs and environment.
This chapter deals with the specifics related to various types of antenna. We will consider everything from an isotropic radiator
(Dipole) to a J-Pole.
Packet radio is one of those communications modes that will reflect on the system operator if he or she fails to provide the antenna
that has the best radiating and capture effect to it. In fact, if the antenna is not constructed and erected so as to provide good capture
to signals and have the lowest noise component
with respect to terrestrial noise, then no one is to
blame except the operator who is in charge of the
installation.
I am as meticulous as A.J. the day before race day.
Don't just walk the race track, look for the bumps
and crevices. The antenna for your packet station is
about to become your doorway to the world.
Every one who has spent any time around me will
affirm that, "Buck won't skimp when it comes to
his antenna."
I am very particular where my antennas are
concerned. When I go to buy cable and connectors,
I purchase the best available coax and connectors.
When I go to buy cable or connectors, I specify silver
flashed connectors and cable of the best quality. Over
the years, that is the part of my station that will get the
least attention after it is installed, so I want it to
withstand the elements and provide dependable
communications for a long time.
I am very picky about the antennas and associated
components of my antenna system. With over forty years as a amateur, and over forty five years as a Senior Telecommunications
Engineer, I’ve learned a very valuable lesson early on. SIGNAL QUALITY begins at the tip of the antenna, and it travels down
through the transmission-line and reflects off the operator at the other end. Let your reflection be a good one.
RADIATION and RESONANCE:
Antennas can be constructed to radiate with directional, omni- directional, and bi-directional patterns.
The kind of pattern desired, depends on the coverage area requirements. Likewise, the type antenna selected, will determine the
kind of pattern you will have. Another major factor in antenna selection and installation is the distance above the ground that an
antenna is suspended.
Antenna theory as related to antennas suspended in free space states simply that the ground below will provide a reflection or
mirror effect. This mirror effect gives an antenna the appearance of having greater gain when the antenna is mounted at distances
that are "in- phase", or a given wavelength above the earth. The greater the height, the greater the gain.
Section 1; Packet Radio “The Basics” A Packet Primer for the new Packeteer __ Page 14
It goes without saying, (but I will anyway) HF beam antennas with long elements, and towers with guy-wires affixed near the top,
don't work well together when the beam is vertically polarized. Something will have to bend or break, either the guy-wire or the
element that are in each others path. For this and other reasons, most HF beams are horizontally polarized.
VOICE vs DIGITAL:
Don't be deceived by the heading of this section. I am not about to begin a rebuttal between these two modes. My intention is to
look into the types of antenna that is best suited for the digital mode of communications, as related to the antenna commonly used
for voice communications. From the beginning of this chapter, we have moved in this direction.
If it is distance you want, then the class of beam antenna that we use for voice will be sufficient. If it is coverage you prefer, again I
prefer the beam type antenna as a power booster. I tend to try for a happy medium with respect to the digital and/or packet modes.
The yagi type antenna, in a horizontal configuration is one way to go if you want coverage, and reduced wind resistance.
That happy medium I spoke of takes the form of a vertically polarized yagi and/or a cubical quad. My preference is the latter;
primarily because the "QUAD" is well known for its favorable gain/bandwidth characteristics.
There is a second, and more important reason I chose the cubicle QUAD. The cubicle quad offers a better signal to noise ratio
because influence from terrestrial noise is greatly reduced when receiving with a cubicle quad antenna. This inherent rejection to
terrestrial noise is one of the reasons we might consider the quad for use in a digital data medium.
Section 1; Packet Radio “The Basics” A Packet Primer for the new Packeteer __ Page 15
THE ANTENNA IS THE KEY "ELEMENT":
The antenna for digital as well as any other modes of communications is only as good as the transmission line that feeds the
antenna. Consult the handbooks and the catalogs for the latest and greatest coax or transmission feedline. Look at the
manufacturers printed specifications for a given type of feedline or coax. When the (VHF/UHF) coaxial cable runs are less than
100 feet, I spec for Belden 9913. When the VHF/UHF cable runs require MORE than 100 feet, I spec for Andrew LDF-4-50 or
larger “heliax.”™ hardline.
The main points of interest are the specs regarding the loss factor (expressed in DB) per hundred feet, the velocity factor, and the
frequency at which the measurement was taken. Over the long haul, the "hard- lines" or multiple shielded coax cables will prove to
be the better value.
The coaxial (coax) cable or the transmission line plays a major role in the antenna performance. The coax is a very vital part of the
overall antenna system, but the coax has a personality of its own and can reek havoc if it is not cut to or "tuned" for optimum
performance along with the antenna. It is even more important to say that antenna performance will depend on the behavior of the
transmission line at the time of antenna tuning or setup. In other words, if the coax is not prepared before the antenna is tuned,
then tuning of the antenna will not render optimum performance.
The coax is the "life-line" that delivers the energy to the antenna. since the energy is handled by the coax, this means that the coax
is either an external extension of the "tank circuit" or it is part of the antenna, but which is true.
This is not a trick question, but a way to make a statement that can be easily remembered. The antenna feed line is BOTH; Because
the complete antenna system is part of the tank circuit.
Wow! Now we are beginning to understand why the antenna should be tuned.
Section 1; Packet Radio “The Basics” A Packet Primer for the new Packeteer __ Page 16
Chapter Four
USING A PACKET BBS:
Because there are so many variations and versions of Packet Bulletin Board Systems (BBS), I've put together a composite of
the most used BBS commands. In the list of commands that follow, I will address instructions that are in general use with
most of the full service Packet BBS types. These commands are closely associated with, but not related to, the common
telephone type BBS.
As a matter of interest to the Packet BBS user, there is no waiting period to access other "WHAT" files sections of a Packet
BBS. Packet BBSes allow the immediate access to all levels of the BBS where the telephone BBSes often require a 24 or
48, hour (and sometimes a week) waiting period after initial access, before the user is allowed full BBS operating privileges.
Once you have answered the four questions, BBS access is there ready and waiting at your service. Just remember that
other users await access to the BBS so limit yourself. This same consideration may be in your favor at a later time.
Some BBSes allow multiple connects to them. When this is the case, BBS activity may slow down while multiple users are
downloading files from the BBS.
A connect to your local area network (LAN) BBS is made in the same manner as a connect to another Packet station. If this
is your first connect to the BBS, you will need to provide some information about yourself. There are four questions, and
the answers to them are short, so the time spent answering these questions are not like the complex answers that were
needed when you accessed a telephone BBS.
If it is your first time on the bbs you will be asked to enter your NAME, QTH, ZIP CODE and HOME BBS. The format
is as follows.
N BUCK
NQ LYNCHBURG, VA
NZ 24550
NH WD4ELJ
The N command can be used to register your name or QTH. You should enter both of these. To enter your name type N
yourname.
Example: N BUCK
To enter your QTH, use the command NQ your QTH.
Example: NQ EVINGTON, VA
To enter your ZIP or Postal Code, use NZ code.
Example: NZ 24550
To enter the BBS that you use to receive mail at, use NH callsign.
Example: NH [Your home BBS]
The BBS will then greet you using your name; In some cases the BBS greeting will contain both the name and callsign.
After the greeting a list of abbreviated commands will appear on the screen.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” A Packet Primer for the new Packeteer __ Page 0
The greeting may appear similar to the following:
WD4ELJ> Hello BUCK, K4ABT Welcome to WD4ELJ BBS [BBS type/number]
WD4ELJ> A,B,C,D,G,H,I,J,K,L,M,N,P,R,S,U,V,W,X,?,*
The following is a list meanings for the abbreviated command letters shown above.
B - Bye C - Conference D - Download G - File search H - Help
I - Information J - Calls heard K - Kill message L - List Messages M - Message of
N - Enter name/qth P - Path to call R - Read message S - Send Message U - Current users
V - VERSION/INFO about BBS W - What files X - Expert
?x- Info about command x * - Comment line
The Abort command can be used to abort the output from many of the BBS commands, like Download, List and Read for
example.
The Bye command disconnects you from the BBS. Use it when you are done!
The Conference command should not be used on the BBS if it is on a LAN frequency with high usage. The conference
mode of a BBS can present a grid-lock situation if the BBS is being accessed by other users at the same time the conference
is in use.
The Download command is used to read a file stored on the system. The format of the command is "D filename" where
[filename] is the name of the file to down load.
To see what files are available for downloading, use the W command. To download a file in a subdirectory, use D
FILENAME.
I by itself gives hardware configuration of the system.
ID gives a list of the ports and digipeaters/gateways available.
The J command lists stations recently heard on the various ports and stations that recently connected. Use the P command
for path to stations that have connected recently.
The K command is used to kill (delete) old messages from the system. You can kill only those messages that are to or from
your station. The format of the command is K, space, and then the number of the message to delete. You can also use the
command KM to delete all messages TO you that have been read.
Use the command KT[msg#] to kill NTS traffic you are going to deliver.
The List command lists selected message headers. The following formats are available:
· L - List messages since you last used the B command
· LB - List bulletins (all of them, use with care!)
· LM - List messages to or from you (List Mine)
· LN - List messages with type of N (List New)
LL # - List the last # messages Example: LL 10 L< callsign - List messages from callsign
Example: L< K4ABT [This would list all messages FROM K4ABT] L> callsign - List messages to callsign
Example: L> K4ABT [This would list all messages TO K4ABT]
Section 1; Packet Radio “The Basics” Section 2; Revised, 2009 X1J4 System Node Operator’s Handbook
Section 1; Packet Radio “The Basics” A Packet Primer for the new Packeteer __ Page 18
For a short description of the commands at your Packet BBS, use H command. For more information about a particular
command, type ?x where x is the letter of the command.
Putting * at the beginning of a line makes it a comment. It also suppresses the next command prompt (but the system will
be waiting for another command). * is useful to answer the SYSOP if you get a MESSAGE FROM SYSOP ...
ONE FINAL NOTE: After you read any messages directed to you, please kill that message using the KM command.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 19
SECTION II; The X-1J4 System Node Operator’s Handbook!
Chapter Five
WHAT IS A PACKET NODE ?
The X1 node is beginning to attract many users, and it is
a "natural" for our Local Area Networks (LAN)
frequencies. Not only can it be used as a node to connect
out of the LAN. It also doubles for use as round-table
packet session when using the "TALK" command/mode.
In version X1J, there is an add-on hardware modification
that allows the users to examine their deviation
(modulation) level. If there is too much or too little
deviation, the users can adjust it accordingly. Further
connects to the node will allow them to determine when
the Frequency Modulation (FM) is set to the correct
swing.
The outgrowth of this node can be used for networking,
in a network of several nodes. There are many features
that time and space prohibit explanation here. To find
out more about this new networking node see the August
and September 1993 issues of CQ magazine.
The X1J code is burned into a 27C512 EPROM which
fits into the TAPR TNC-2 or clones, such as the
MFJ-1270C, and MFJ-1274C.
By now you are aware of the need for an EPROM burner.
One of the EPROM burners that I'm most familiar with is
the PB-10 from Needham Electronics. The PB-10
EPROM burner supports the latest EPROMS for user
friendly program for EPROM maintenance.
As I described in the August 1993 issue of CQ magazine
(PACKET USERS NOTEBOOK), the EPROM for the
X1 node is burned into a 27C512 EPROM in two parts.
The Needham Electronics EPROM burner makes the
process easy because we can set the first address to blow
the EPROM from 0000 to 7FFF, then the second half of
the EPROM is burned from address (HEX) 8000 to
FFFF.
The EPROM programmer makes the job easy is through
if it has a Zero Insertion Force (ZIF) socket.
The ZIF socket of the Programmer should accept several
sizes of EPROMS including the ONE MEGABYTE
EPROMS (27C1001, 27C1010 etc).
INITIALIZING:
Once the EPROM is installed into the TNC2 or clone,
the initializing process is easy. Turn it ON, set the
parameters, the rest is history.
The node sends out update broadcasts to inform other
nodes that it is active. The operating parameters are set
in the firmware and are available for easy changing by
the SYSOP. The parameters shown under the "P"
command of the X1 nodes parameters are similar to those
used in the early thenet 1.01 node. However, in the
X1J4, there are additional commands contained in 6
other parameter sections. These are associated with
specific functions and features like the MODE (17
commands), METER (10 commands), MTU, IP
addressing, ACL, and ADC 1&2.
The credit for this new network node firmware goes to
the developers; They are:
Dave Roberts G8KBB
Dave is the author of the X1 code. The X1 version is
based on the original thenet 1.01 platform that was
developed by the Nord><Link group.
Neville Pattinson G0JVU
Neville supports the hardware projects associated with
the X1 node(s).
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 20
Chapter Six
Reviewing the New Features of the X1J4 Node
1. An S-meter function in the heard list
2. A Voltmeter function for the other two ADC channels
3. The ability to change the user's command prompt list
4. The ACL function has had a feature added to speed it up
5. A complete IP router,
6. The Receive Deviation meter,
7. Control of 'Slime Trails',
8. Information text messages 160 characters long,
9. Multiple line INFO, CTEXT and BTEXT messages,
10. Nodes broadcasts occur 60 seconds after power up,
11. Optional reconnect to the node after remote disconnect,
12. PARMS, MODE etc may be managed by offset & value,
13. Digipeat uplink & downlinks may be selectively enabled,
14. Level 4 retries ( min ) is now 1,
15. An MTU command allows MTU settings to be changed for IP use,
16. Node alias handling is optionally case sensitive,
17. TALK will optionally pass 8 bit data,
18. The ability to remotely set the node's alias,
19. The ability to listen for 3 extra aliases & invoke BBS etc,
20. Selective node broadcast control for 'hash' nodes,
21. A UI command to send arbitrary UI commands,
22. Access control list capabilities,
23. Multi-user conferencing ( the 'TALK' command ),
24. A CWID keyer,
25. Better SYSOP authentication,
26. MHeard list showing callsigns, packets heard & time since last heard,
27. MHeard list shows whether a station is a node and / or TCP/IP station,
28. A Closedown command to remotely shut the node down,
29. A DXCluster command that operates like the BBS & Host commands,
30. A Btext command to set the node's beacon text message,
31. A Ctext command to set an optional alias connect text message,
32. The ability to enable or disable any command,
33. Improved command prompting with only valid commands shown,
34. Routes show optionally as alias:callsign or callsign alone,
35. Additional control over system reset,
36. KISS as an alternative to the crosslink protocol,
37. Hardware handshake controlled host mode operation,
38. MODE command for configuring additional parameters,
39. BBS command to auto connect to a remote BBS,
40. HOST command to auto connect to another BBS or Host,
41. BYE or QUIT commands to disconnect,
42. STATS command to display internal statistics,
43. MANAGER command for system manager access,
44. AUDIT command to set system audit levels,
45. Changes to the NODES command,
46. An improved nodes broadcast algorithm for the crosslink port,
47. Split port nodes broadcast intervals,
48. Ability to enable & disable nodes broadcasts selectively on each port,
49. CQ apologises nicely if disabled,
50. Most Escape commands have been replaced with MODE parameters,
51. Beacon messages may be digi'd,
52. CALIBRATE command for remote checking of Tx deviation,
53. LINKS command to show current level 2 links,
54. Configuration of the beacon period,
55. Auto routing of 'connect' to either BBS, DXCluster or HOST,
56. Remote dump of entire neighbor lists for all nodes.
57. The ARP table is automatically updated from ARP requests & replies
58. The node maintains a second heard list of L3 Netrom nodes that gateway through the node
59. The RxDeviation & Smeter ADC channels may also be used as arbitrary inputs instead
60. A defensive port flush function added
61. Link list integrity checking has been extended to check reverse links
62. The USER list shows circuit choke status for patchcord connections.
63. The ADC* text messages are now 12 characters long
64. The ACL checks the end user call as well as the node call in accepting connections.
65. Lines that start with '#' are ignored by the switch
66. A default IP route entry may be made
67. Support for the TexNet '*** LINKED to' syntax
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 21
DEFINING A FEW OF THE X-1J4 FEATURES:
MHeard
If enabled, the heard list shows the last few stations
heard. The number of entries is limited and set by the
sysop so any stations not heard for a while may get
pushed out of the list by others heard.
Assuming that a station is not pushed out in this manner,
the display shows the number of packets heard from that
station since it appeared in the list and the time since it
was last heard. The time is hours, minutes and seconds.
The list also shows the port on which the station was
heard (port 0 is the radio port), and if it hears IP frames
or Net/Rom frames, it adds a note to show that the station
is a node and/or a TCP/IP station.
If the list is long enough so that a station is not heard for
12 hours, it will get deleted anyway.
The list may also show a column headed 'Dev.'. This will
only be present where the sysop has added to the node a
small hardware add-on that measures the received signal
audio level. Specifically, it gives an indication of the
peak audio level.
By means of a software configuration control and prior
calibration, this gets converted into an indication of the
transmitting station's signal deviation. It does this by
sampling the audio level after every valid packet.
Care must be taken over its interpretation. It does not
measure independently the two tone levels - it is assumed
that whatever local standards that relate to pre-emphasis
(i.e. use it or not) have been implemented.
PACKET MODULATION / DEVIATION IS
IMPORTANT:
The 1200 baud Packet modulation / deviation is
important. In contrast to the 5 KHz deviation of VHF
FM voice, Packet modulation should be set to, or just
below 3 KHz.
Often, packet stations are set up, and the audio level
tweaked until it appears to work reasonably error free.
The idea of this add-on is that, having done that, you
then connect to the node and display the heard list to see
an indication of your actual deviation. It may then be fine
tuned to set it correctly. Local advice must be taken over
the correct setting as it depends on the channel spacing
being used ( e.g. 12.5, 25 or other KHz ).
The METER command is set ON, or made active by the
sysop when the system manager sets the meter command
to a value other than 0 (zero). He enters the command
mode using the password and then sets the sysop
"METER" command to a number above 0 (zero) and
below 256.
The sysop first calibrates the deviation meter within the
node while it is on the work bench before installation at
the node site. Setting the METER command to 0 (zero)
will turn the deviation feature OFF.
Provided the meter is calibrated according to the sysops
"DEVIATION" manual, the sysop might set the METER
command to 20. Thus the reading would be multiplied
by 255, and equate to about 5 KHz for full scale reading.
METER 10 would therefore support a reading of 2.5 KHz
full scale. eg; 10 X 255 = 2550 Hz or 2.55 Khz.
Once he has put the node at the final site, the METER
command may be used to tweak the DEVIATION for the
final reading that corresponds to the deviation from a
known source.
ONCE THE DEVIATION Analog to Digital Converter is
installed into the TNC, and calibrated, the receiver
volume should not be moved! To change the input to the
ADC will cause erroneous readings for users of the DEV
X-1J node.
In addition, the deviation reading will give the wrong
answer when the following conditions exist:
· If the transceiver modulation contains too much
distortion.
· If the transceiver too far off frequency.
The list of features in the X1 node is too long to cover
here, however you can find a full explanation of the X1
node in the August and September 1993 issues of CQ
magazine.
In addition, the new X1J release 2 node has added the
Voltage meter, the "S" meter, and Temperature sensor
to the node firmware.
The sysop can easily install this feature filled PC board
add-on.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 22
The add-on unit cost is less than $50, wired and tested.
See JUNE 1994 CQ Magazine, PACKET USERS
NOTEBOOK.
TALK:
The Talk command allows a group of users to hold a
conference call. It also allows a user to send a message to
another user of the node provided that user is connected
to the switch but is not patched through to another station
and is not currently trying to connect to another station.
A user enters the conference by giving the command
'talk'. He/she gets a message informing them of this and
reminding them that the command to escape from the
talk command is '/exit'. Any other users currently in the
conference get a message from the node telling them of
the callsign of the user who has joined them.
At this point, every line sent by a user in the conference
is copied to all other users in the conference, preceded by
their callsign.
To exit from the conference, the command '/exit' is used.
This causes a message to be sent to the user.
At the same time, all of those left in the conference get a
message from the node telling them of the station who
has left the conference.
If you force a disconnect, the other stations are not told of
your departure.
A string of text may be entered on the same line as the
talk command when the command is given.
If this is done, before the user is connected to the
conference, that string of text is sent to all the other users
of the node who appear in the "user" list but are not
connected to anything else.
For example if while I'm connected to the node as a user,
and W4WWQ connected to the node and typed:
TALK , Hello Buck can we have a chat? If so,
PSE type TALK
Then I would receive the following on my screen.
Additionally, and other users connected to the node, and
not connected through would see the following:
W4WWQ > K4ABT>>TALK ,Hello Buck can we
chat? If so, PSE type TALK
Each user in a round-table receives all the information
from every other user in the NET or round-table.
The only exception to this is that sysops are not sent the
message.
OTHER SOURCES OF INFORMATION FOR THE
DIGITAL HAM:
To keep abreast of the many useful devices for the digital
ham, be sure that he or she has a current subscription to
CQ magazine. The PACKET USERS NOTEBOOK
in CQ magazine gives the digital Amateur a first hand
look at what is happening in the world of digital
communications.
CQ de BucK4ABT
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 23
Chapter Seven
Understanding theNET X-1J 4 Node
TheNET X1 supports multi-frequency operation without
the need for unconventional multi-port digipeater
hardware. A dual-frequency node, for example, consists
of a two TNC2 (with X1 in each) connected together with
an RS232 interface cable.
Configuring a TheNET X1 node for three or four
frequencys is just as easy; A TNC2 is used for each
frequency (or baud/speed), and the multiple TNCs are
interconnected via their RS232 ports using a diodematrix
interface.
In addition, it is possible to configure a dual-frequency
TheNET X1 node in
which the two TNC2s are not co-located. Instead of an
RS232 cable, the TNC interconnect can employ a
dedicated telephone line, fiber optics or other media as a
high-data rate backbone.
TheNET X1 uses an asynchronous variant of AX.25 over
the interconnect, it is not necessary that it be an errorfree
connection. This opens up fascinating possibilities,
such as a fiber-optic or satellite linked dual-frequency
node which may be accessed from any point coast to
coast.
AUTOMATIC ROUTING:
TheNET X1 automatically takes care of the routing of
traffic between one node and another. A user needs to
specify just the desired destination, not the route.
Each node keeps track of the other nodes in the network
and the various possible paths that may be used to reach
them. If a node or path becomes unusable due to
equipment failure or poor propagation, TheNET X1
automatically switches to an alternate route (if available)
to circumvent the outage. Conversely, when a new node
is placed on-line, other nodes automatically incorporate
the new node into the network routing structure. Such
routing changes are handled dynamically, without
disrupting user connections in progress.
TheNET X1 supports three methods of updating its
routing information: local, remote, and automatic. Initial
routing information may be entered manually by an onsite
operator using a local terminal.
Routing changes may be made remotely by a SYSOP or
network manager over an ordinary packet radio
connection randomized verification algorithm effectively
prevents changes by unauthorized operators. In addition,
TheNET X1 nodes broadcast routing information to each
other as defined in the Param and Mode settings.
Furthermore the nodes can be set to "locked-path"
settings, thus eliminating the need for any broadcast at
all. In any case, the node(s) may be enabled to
incorporate new nodes and to bypass outages in real-time
without manual control.
THE "CQ" FEATURE:
TheNET X1 allows a user to broadcast a CQ from a local
or distant node, and enables other stations to replay to the
CQ using the high-level facilities of the network. A
user's CQ request remains active for up to 15 minutes,
during which time it appears in the node's user directory.
NODE IDENTIFIERS:
Each TheNET X1 node is identified in two ways: by a
valid amateur callsign
permanently encoded into each copy of TheNET X1, and
by an arbitrary node identifier established by the node's
sysop. Identifiers may be up to six characters long or
three-letter city designators similar to those used by
airports to identify the neighboring city or location.
Some examples of these are ATL for Atlanta, MCN for
Macon, CHI for Chicago, or JVLfor Jacksonville, etc.
Node identifiers appear in node station identification
beacons, and are passed to other nodes during the
periodic routing broadcasts (PARAMS Parameter
number 7).
Despite its internal advanced networking capabilities,
TheNET X1 is exceptionally easy to use. A new user
needs to learn only one command, CONNECT, to
establish cross links to other nodes or downlinks to other
user stations.
More sophisticated users may wish to use the NODES
command to list the callsigns and identifiers of other
network nodes, and the USERS command to find out
who else is using the node.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 24
When a Packet network user or the system node operator
(SNO) issues the “U” or users command, the node will
respond with the nodes; alias, callsign, SSID and a
number enclosed in parentheses; e.g. (721)
is the actual number of free buffers in the node. One
buffer consists of
32 bytes data and 4 bytes for linkage, 36 bytes in total.
All stored
information uses buffers within the nodes memory
(RAM) and the list of
other known nodes takes up buffers too.
The reason why this number of free buffers is made
known to the user, is to tell him the load on that node. If
for any reason TheNet X-1J4 runs out of free buffers, a
reset will be made causing all users to be disconnected.
During regular operation this is almost impossible, as
with the X-1J4 TheNet where the parameters are
properly set, there will never be a shortage of buffers (you
cannot load too many packets one after the other into
the node).
SYSTEM NODE OPERATOR OR “SNO”
The System Node Operator (SNO) can use Manager or
SYsop command to validate the SysOp/MAnager
privilege in the node. This enable the SNO to make
manual changes to the routing table, IDENT, to establish
a mnemonic node identifier, PARMS to set or display
various node parameters.
The RESET command can allow the SNO to perform a
warm-start, or by issuing “RESET *” the node can be
“cold-started” thereby resetting all the parameters to the
default settings that were originally burned into the X1J4
EPROM.
Each TheNET X1 node also supports the functions of an
ordinary AX.25 digipeater. Users need not make use of
the high-level networking functions of TheNET X1
unless they want to. Digipeater owners can upgrade their
sites to TheNET X1 nodes without disrupting users.
Multi-frequency TheNET X1 nodes provide multi-port
digipeating as well. Node identifiers may be used in lieu
of node callsigns when specifying a digipeated path.
When you issue a BYE, QUIT, or disconnect from the
node where you made access to the system, TheNET
X1J4 automatically takes care of disconnecting your
circuit to the nodes you used to downlink to the
destination station.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 25
THE FOLLOWING ARE DEFINITIONS OF TERMS DEFINITIONS ASSOCIATED WITH THE X1J4 NODE:
· DIGIPEATER - A station capable of digitally repeating AX.25 frames as specified in the AX.25 protocol
specification. Generally, refers to an unattended, wide-coverage digital repeater, often located on a hilltop.
· NODE - A packet radio station utilizing TNC2 hardware and implementing an EPROM that contains the
theNET X1 firmware. In most applications, this refers to an unattended, wide-coverage station located at high
elevations such as a hilltop, mountain, tall-tower, local water supply tower, or high-rise building.
· SYSOP - The node SYStem OPerator, or the Network MAnager who performs administrative configuration of
the X1 node.
· USER - Any amateur packet radio station using AX.25 protocol. In the context of this document, a BBS or
other automated server is considered a "user".
· DUAL-FREQUENCY Node - A pair of TheNET X1 nodes operating on two different frequencies, and
coupled together by means of an RS232 cable.
· MULTI-FREQUENCY Node - Three or more TheNET X1 nodes operating on different frequencies, and
interconnected via their RS232 ports using a diode-matrix coupler.
· LINK - An AX.25 connection involving a node at one or both ends. Node-to-node links always use AX.25v2
protocol. User-to-node links use AX.25v2 protocol if the user's TNC supports it, otherwise AX.25v1.
· UPLINK - An AX.25 connection between a user and a node, initiated by the user. An uplink is usually a
direct connection, but may be digipeated if necessary.
· DOWNLINK - An AX.25 connection between a node and a user, initiated by the node. A downlink is usually
a direct connection, but may be digipeated if necessary.
· CROSSLINK - An AX.25 connection between two adjacent nodes. A crosslink is usually a direct connection,
but may be digipeated if necessary. A crosslink between two nodes is initiated by one of the nodes when first
establishing a circuit which traverses the route segment between the two nodes.
· LOCKED ROUTE - A path or route that has been installed into the route and/or node table of a TheNET
node. This method of route control presents the node sysop with a means of “locking” routes between nodes.
Locking routes also serves as a safeguard that assures the sysop that the nodes will use the same route(s)
regardless of atmospheric conditions or “lift” propagation.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 26
Chapter Eight
Using the advanced features of the X1J4 Node
Suppose you are a user with access to a local node, and you want to contact another user station who is also within range of
the same node. You can, of course, connect to the other station "the old way" by using the node as a digipeater. To take
advantage of the store-and-forward capabilities of the node, however, you would use this two-step procedure: (1) connect to
the node ("uplink"); then, (2) issue a CONNECT command with the callsign or identifier of the other user station
("downlink").
UPLINK-DOWNLINK CONNECTIONS:
All AX.25 frames include the callsigns of both the originating station and the destination station. When you request a
downlink, the node "adopts" your callsign as the originating station (rather than using its own callsign). This is necessary
so the destination station can properly identify you as the connecting user station. The node does NOT use your "exact"
callsign, but if it did, and, if there happened to be a direct path between your station and the destination station, that station
would then see two stations using the same callsign. This can create confusion at the destination station or on the
network... BIG-TIME!
To avoid this problem, the down linking node "adopts" your basic callsign, by changing the SSID (or adding a callsign
suffix) from N to 15-N. For example, if your callsign is NT4XXX, the downlink uses NT4XXX-15; if your callsign is
W4KGS-2, the downlink uses W4KGS-13; and so forth. To utilize the full store-and-forward capability of the nodes, you
would use a three-step procedure:
(1) Connect to your local node; then.
(2) Issue a CONNECT command with the callsign or node identifier of the distant node.
(3) Issue a CONNECT command with the callsign of the other user station.
UPLINK, CROSSLINK, AND DOWNLINK, CONNECTIONS:
When you perform step (2) of this procedure, you are asking your local node to create a "circuit" for you between your local
node and the distant node. If the two nodes are sufficiently far apart, the circuit may have to pass through several
intermediate nodes. In any case, the routing is performed automatically by the node. Your circuit is carried by a series of
AX.25 "crosslinks" between pairs of adjacent nodes.
USING THE “CQ” FEATURE:
The CQ command is used to broadcast a short text message from a node, and to enable other user stations that receive the
broadcast to connect to the station that originated the broadcast. An example is:
CQ This is George, Connect to me at the CALL & SSID displayed
All text after the CQ is optional and can be any string up to 77 characters long.
In response to a CQ command, the node broadcasts the specified message in "unproto" mode, using the callsign of the
originating user (with a translated SSID) as the source and "CQ" as the destination. The broadcast is made in the form of
an AX.25 UI-frame.
If WA4GSO in Wadesboro, North Carolina sent the CQ through several nodes to a node in Macon, Georgia, the display at
the Macon node would appear similar to the following:
WA4GSO-15>CQ: George in Wadesboro, NC
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 27
After making the broadcast in response to the CQ command, the node "arms" a mechanism to permit other stations to reply
to the CQ.
A station wishing to reply may do so simply by connecting to the displayed callsign shown in the local Macon node
broadcast (WA4GSO-15). A CQ command remains "armed" to accept replies for 15 minutes provided that PARMS
Parameter 15 is set to 900, or until WA4GSO issues another command or if he drops the link (disconnects).
Any station connected to the MCN node at Macon, Georgia can determine if there are any other stations awaiting a reply to
a CQ by issuing the USERS command. If there is an "armed" CQ at MCN node, the station who issues the USERS
command will see:
(Circuit, WA4GSO-7 Uplink) <--> CQ WA4GSO
The station may reply to such a pending CQ by issuing a CONNECT to the user callsign; In our example; C WA4GSO-15,
the callsign and SSID specified in the CQ(...) portion of the USERS display. It is not necessary for the station to disconnect
from the node and reconnect.
Users of the CQ command are cautioned to be patient in awaiting a response. Your CQ will remain armed for 15 minutes
and will be visible to any user who issues a USERS command during that time. Consequently there's no point in issuing
additional CQs - give other stations a chance to reply to your first one! Note the setting of PARAMETER 15 for duration of
the CQ call, time-to-live.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 28
Chapter Nine
Constructing, Installing, and Configuring TheNET X1J/4 NODES
DUAL AND MULTI-FREQUENCY NODE (STACK) OPERATION:
To realize the full potential of TheNET X1's high-level
networking capabilities, it is an excellent idea to
minimize
interference between local (uplink/downlink) and longhaul
(crosslink) traffic. One good way to accomplish this
is to reserve one radio frequency exclusively for internode
traffic, to provide end-user access to the nodes on
one or more separate frequencies, and to discourage
(ideally, to prevent “ACL”) end-users from using the
inter-node "backbone" frequency. This approach requires
network nodes that can access two or more frequencies.
A REAL “SIX-PACKet.” NODE-STACKS
PERFORM CROSSLINKING BETWEEN TWO OR
MORE FREQUENCIES OR BAUDRATES. SIX
MFJ-1270C’s EQUIPPED WITH X-1J4 EPROM .
The node stack shown here is located atop 3000 foot,
“No Business mountain” in central Virginia.
The MFJ-1270”C” can be equipped with the add-on MFJ-9600 (9600 baud) Modem. The MFJ-1270CQ Turbo is a
complete 300, 1200 or 9600 baud TNC. All MFJ-1270 “B” / “C” and PacComm TNC2 clones are X-1J4 TheNET
node compatible.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 29
Chapter 10 Section II
DUAL AND MULTI-FREQUENCY NODE OPERATION:
TheNET X1 supports such multi-frequency operation without the need for exotic multi-port digipeater hardware. A dualfrequency
node, for example, consists simply of a pair of standard TNC2s (with TheNET X1 in each) connected together
with a simple RS232 cable. Each TNC takes responsibility for handling traffic on a single frequency; cross-frequency
traffic is passed over the cable between TNCs at relatively high speed. (See installation instructions for wiring of the
interface cable below.)
This gateway interface cable enables node communications between two X-1J4 nodes, port to port. This configuration
allows the SNO to bridge from one frequency to another, or from one baud rate to another, OR BOTH.
Set the DIP switches to the same RS-232 port baud rate. The DIP switches are located at the rear of the MFJ-1270B and
MFJ-1270C TNC’s.
Most applications at VHF have the 1200 baud node DIP switches 5 & 7 ON and all others OFF. On the 9600 baud
node/port set DIP switches 5 * 8 ON, all others OFF.
On the late model MFJ-1270”CQ” Turbo TNC’s the RS-232 baud rate can be set at 19,200 baud. Be sure that both TNC’s
have this capability, otherwise, use the RS232 port setting of 9600 baud.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 30
Configuring a multi-frequency TheNET X1 node for three or more frequencys is almost as easy as dual-frequency
operation. A TNC2 with TheNET X1 installed is used for each frequency. Once again, the TNCs are interconnected via
their RS232 ports. Interconnecting three or more TNCs requires nothing more elaborate than some isolation diodes
between the RS-232 ports.
DIGIPEATERS VS. NODES:
The AX.25 protocol was originally designed for point-to-point (non digipeated) connections. AX.25 was subsequently
extended to accommodate one digipeater, and later extended again to allow up to eight digipeaters. As all experienced
packet radio users know, however, AX.25 is practically unusable for digipeat paths exceeding two or three "hops". The
reason for this is that AX.25 digipeaters do not fully provide error control. For an AX.25 packet to traverse a multi-hop
path, it must not fall victim to a collision or other error during any of the hops; otherwise, it must be retransmitted by the
originating station and start its journey all over again.
The probability that a data packet can complete its journey through several digipeaters deteriorates rapidly as the number of
hops increases. Since the usual time for a five-hops of digipeating is 35 seconds, the average elapsed time to get the packet
through will average about 75 seconds.
Using TheNET X1 nodes instead of ordinary digipeaters changes this situation dramatically for the better. When the
Wadesboro, North Carolina user transmits a packet destined for Macon, Georgia, it is received by the local TheNET X1
node serving Wadesboro, North Carolina. That node immediately passes the packet to its neighboring node to the south,
and sends an acknowledgment back to the user. This process is repeated five times in all. As a result, the average elapsed
time to get a packet through decreases to less than 15 seconds, about 700% improvement in throughput. For longer paths,
the payoff is even more dramatic.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section II; TheNET X1J4 System Node Operators Handbook __ Page 31
THE MOST FREQUENTLY USED SysOp & User COMMANDS:
The Command Interpreter within the node firmware supports several commands including; CONNECT, TALK, MHeard,
ROUTES, NODES, USERS, PARMS, INFO, RESET, and SYSOP. Here are a few of the more commonly user level
commands.
The CONNECT command enables a user to request a circuit to a distant node, a downlink to a user station, or a direct
connection to the local host terminal (if there is one) attached to the node.
The NODES command permits a user to obtain a list of other nodes for which the local node has routing information, and
to examine the routing details to any particular node. It also allows an authorized SysOp to add, delete, or change routing
table entries manually.
The USERS command displays a summary of the current activity at the node, including information about active uplinks,
downlinks, circuits, patch cords, and users in command mode.
The PARMS command displays a series of numeric node parameters, and allows an authorized sysop or network manager
to change the values of these parameters. The INFO command displays information about the node which has been
uploaded by the node sysop or network manager. TheNET X1 allows a sysop to change the information remotely. To
delete current INFO from the node, the sysop (while in the sysop command mode) may enter an "I" followed by an asterisk
i.e.; I *. A space is placed between the I and the asterisk.
The MHeard command enables the user to see a list of stations recently HEARD by the node. In addition, it the X1 node
is equipped with the Suffolk Data Group (MFJ model MFJ-52) DEV add-on PC board, the MHeard list will reveal the users
deviation, signal strength, voltage at the site, and the temperature at the site.
The RESET command permits a sysop to reset (warm-start) the node remotely. To place the node firmware at DEFAULT,
perform a RESET<space> *(asterisk).
Simply stated: RESET *
Another way to perform the reset is to send the node:RESET <space> RESET <Enter>
Stated: RESET RESET
SYSOP VALIDATION:
Authorized sysops can make manual updates to routing table entries with the NODES command, modify various node
parameters with the INFO, MODE, PARAMS, and other node commands or do full “cold-starts” and “warm-start” using
the RESET command.
To do these things remotely, a sysop must first validate his credentials by means of the SYSOP password, otherwise, the
remote update commands are locked out.
A password string up to 80 characters long is entered into the node by an on-site operator via a local terminal. The
password string cannot be changed remotely. When a remote operator enters the SYSOP command, the node replies with a
list of five random numbers. The sysop must then enter the five characters that correspond to the numbered character
positions in order to have sysop privileges. The section that follows will explain how the sysop deals with the password.
Section 1; Packet Radio “The Basics” Section 2; Revised, 2009 System Node Operator’s (SNO) Handbook
Chapter 11 Section II Revised 9, 9, 2009
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 32
Chapter 12 Section II
SYSOP VALIDATION: (HANDLING THE PASSWORD)
The SYSOP command allows an authorized sysop or network manager to validate his credentials prior to making privileged changes using the PARAMS,
MODE, NODES, ROUTE, INFO, CTEXT, BTEXT or the many other commands associated with the X-1J release 4 of a TheNET node. This also includes
allowing the sysop or manager to perform a “warm” or “cold-start” of the node using RESET or RESET *.
SYSOP uses a randomized validation algorithm which makes it difficult for an unauthorized user to masquerade as a sysop or network manager. The following
text explains how the X1J4 password is applied and executed by the X1J sysop or network manager.
Here is an example of an X1J4 node password:
T H I S I S A P A S S W O R D
Using our password example, we number the password letters in numerical order:
T H I S I S A P A S S W O R D
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
If you need to set parameters, change beacon text, connect text, set DEViation meter calibration or make "MODE" changes; connect to the node and TYPE
SYsop or MAnager. You should receive five (5) numbers. These numbers correspond to a sequence of letters or characters that are used in your password. The
following is an example of the reply from the node after I connect to the node and send the word SYsop or MAnager to the node:
The node responds with; 7 8 15 1 2
Comparing the numbers received to the letter above that number, in my password string, I respond to the five numbers with:
APDTH <Enter>
Notice there are no spaces when I send the corresponding five characters to the node. THERE WILL NOT BE A REPLY FROM THE NODE. You may
also enter letters or numbers before or after the five letters of the password as long as you make sure the five characters are in the order called for by the numbering
sequence of the password. In addition, they must be all together, there are no spaces, and they are in the correct case (CAPS ..etc), as that of the password
programmed into the node.
Another example of my response could be: VAPDTHERE <Enter>
To determine if you have entered the correct sequence of letters or numbers, use the "P" or parameter command to make a
test of the password entry. Send a P, then wait for the 26 parameters to be sent to you from the node as shown in the
following example:
007:K4ABT-7} 100 86 86 255 9 5 900 32 180 3 2 60 4 4 2000 64 10 5 4 10 200 0 0 0 2 1
If the first number is 100, try sending another number to the node, as in this example:
P 66 <Enter>
If your PASSWORD entry was correct, the node will allow you to make a change in the first number of the parameter list,
and you should see the following appear on your screen:
007:K4ABT-7} 66 60 60 255 7 5 900 16 180 2 2 120 4 4 900 64 10 5 3 10 50 18000 0 0 2 1
Notice that the first number changed from 100 to 66. Be sure to return parameter number one back to its original value by
sending the P and the original number. e.g. P 50 [Enter].
CORRECTING MISTAKES WHEN MAKING TEXT ENTRIES TO TheNet X-1J4 NODE:
If at any time you make a mistake when setting BBS, CText, BText, INFO or other text entries, use the asterisk (*) to erase
or delete the text and re-enter it again. As an example, if I mistakenly send; CT SEDAn node etc. .
To clear the Connect Text (Ctext) error; SEDAn node ect... I would send the node; CT * [CT asterisk] This will
clear the CText entry. I would then repeat the entry with the correct case, spelling, etc.... This same procedure applies to
other text entries..e.g. BText, Info, etc….
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 33
Chapter 13 Section II
HOST MODE:
The Host mode supports a local terminal attached to the node. It permits the local terminal to access all of the same
capabilities that a remote user can access. In addition, it supports some specialized "host commands" available only from
the local terminal. For example, it allows
local entry of the password string used by the SYSOP command to validate sysop or network manager credentials.
1) Esc C Connects to the HOST node.
2) Esc P Returns PASSWORD
3) Esc D Disconnects (So does; Bye, Quit, & RESET)
Often a problem occurs at the end of a QSO when one station wants to disconnect, but not before making certain that the
other station has successfully received the first station's concluding information frames. This often resolves itself with a
last-minute flurry of closing remarks. TheNET X1 solves this problem in a more respectable fashion.
If two stations are connected to one another via the network and one of the stations disconnects, TheNET X1 automatically
maintains its connection to the other station until all in-transit information frames have been successfully delivered to that
station. TheNET X1 disconnects only after all in-transit information has been delivered, or after 15 minutes has
elapsed without any "forward progress" in delivering such information.
AUTOMATIC ROUTING:
When you ask one node for a circuit to a distant node, your CONNECT command specifies the callsign or identifier of the
destination node, but the routing is handled automatically by TheNET X1. Automatic routing is handled by the Routing
Manager, and is controlled by its routing table.
The routing table within a node contains a list of all other nodes "known" to the node, together with their mnemonic
identifiers. You can ask to see this list by using a parameter NODES command. The routing table can keep track of
hundreds of other nodes (limited only by the size of available memory and any constraints imposed by the network
manager).
If you want to connect to an especially distant node, it is possible that your local node doesn't know of its existence as it is
not listed in the local NODES display.
In this case, you can use CONNECT to obtain a circuit to a known node nearer the desired destination, and then issue
another NODES command to get a list of the nodes known to that node. This process can be repeated if necessary. For
each known node, the routing table can contain up to three alternate ways to route traffic to that node. The node knows the
quality of each alternate route, and always attempts to use the "best" (i.e., highest quality) route to a destination. However,
if a node or path becomes unusable due to equipment failure or poor propagation, the Routing Manager automatically
switches to an alternate route (if available) to circumvent the outage. Such routing changes are handled dynamically,
usually without disrupting circuits in progress.
The routing table maintained by each node consists of two dynamically allocated threaded lists: the destination list and the
neighbor list. The destination list contains an entry for every other node "known" to this node. This is the list displayed by
the NODES command. The neighbor list contains an entry for only those "neighboring" nodes to which this node has a
direct link.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 34
For each node in the destination list, the routing table up to three routes to that destination node. In this context, a route
simply identifies a neighboring node that is a step closer to the ultimate destination. For each route, the destination list
maintains a "radio port" quality value in the range 192 (best) to 0 (worst).
Routes are maintained in sorted order by quality, and TheNET X1 always attempts to use the highest-quality route
available. It also keeps an obsolescence count , which enables TheNET X1 to purge paths from its routing table when it has
become unusable and remained so for a protracted period of time.
If you are the sysop or network manager, you may observe a more complete routing list with in the X1 node by entering the
sysop command level and sending an "N * *" to the node. The node will return a complete list of all the nodes contained in
the NODES LIST. This list will be displayed in ascending order with up to three nodes to the right of each node showing
the routes and routing order to the neighbor nodes and their neighbor nodes. A user may obtain the route(s) to a single
node by sending the node a single-node path request using the following format:
N<space>[nodename] <Enter>
For instance if the user were connected to a node at Martinsville, Virginia, and wants to know what path the Martinsville
node (MVA) uses to reach the Salisbury, North Carolina (SNC) node, the entry to node MVA would be:
N SNC
Since each node keeps track of many other nodes and the available routes to those nodes, it is important that this routing
information be kept up-to-date to reflect the current state of the network. TheNET X1 supports three methods of updating
its routing table: local, remote, and automatic.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 35
Chapter 14 Section II
ROUTE QUALITY ANALYSIS:
For each route in its routing table, TheNET X1 maintains a route quality value in the range 255 (best) to 0 (worst). This
allows it to keep alternate routes in order of quality, and to select the best available route to a destination. A route quality
value can best be visualized as a fraction (the value divided by 256) which quantifies the speed and reliability of a particular
route in comparison to a theoretically perfect route (an infinitely fast and perfectly error-free path) of quality 256.
For example, a route of quality 230 can be thought of as being "90% perfect" in speed and reliability (230/256 = 0.90). The
quality of each frequency used by a TheNET X1 node is established by the sysop of the node. As a starting point, we
suggest the following values to be used as baud/quality/parameters:
Baudrate Description Quality % Perfect
9600-baud RS232 wire interconnect (2-port) 255 99%+
9600-baud RS232 satellite interconnect (2-port) 252 98%
9600-baud RS232 wire interconnect (3-port) 248 97%
9600-baud HDLC isolated inter-node backbone 240 94%
1200-baud HDLC isolated inter-node backbone 224 88%
1200-baud HDLC user-accessed frequency 192 75%
1200-baud HF frequency 180 70% (Not recommended)
300-baud HDLC HF frequency 128 50%
The quality of a multi-segment route is simply the product of the qualities of each individual segment, where quality values
are treated as fractions with an implicit denominator of 256. For example, a four-segment route that consists of two 9600-
baud RS232 interconnect segments (quality 255) and two 1200-baud HDLC backbone segments (quality 224) has a
calculated quality of 194 (255/256 times 255/256 times 224/256 times 224/256 equals 194/256). Quality calculations are
rounded to the nearest 256th.
In practice, I have found that path quality for a 1200 baud neighbor node should be locked at 192 and path quality for a
9600 baud backbone neighbor node should be locked at 240.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 36
Chapter 15 Section II
DIGIPEATING: & HOST INTERFACE
NOTE: Since digipeating takes priority over other node's network activities, in today's modern network, this is
undesirable. For proper network operation it is recommended that the digi function (parameter #23) be set to off.
Each X1 node supports the functions of an ordinary AX.25 digipeater. Users need not make use of the high-level
networking functions of TheNET X1 unless they want to. Digipeater owners can upgrade their sites to TheNET X1 nodes
without notifying the user population. The users won't notice any change. Furthermore, each multi-frequency node is also
a multi-port digipeater. Each frequency is assigned a different callsign.
Often, the same basic callsign will be used, but with different SSID suffixes for each frequency. (For example, K4ABT-7 is
used for the node at 145.770 MHz. The backbone gateway node to 9600 baud’s at the same location is K4ABT-9. Since the
9600 baud backbone node is in the 440 MHz band, the call/SSID may well have been K4ABT-4. In the latter case,
K4ABT-4 was already in service thus the call/SSID of K4ABT-9 was used instead.
Users who have the mailbox option inside their TNCs make it easy for distant users to know what their mailbox call/SSID
is by employing the SSID of "-1". This format has become a universal user mailbox addressing scheme. It allows a
distant user to connect a node local to a station and issue the call/SSID of a known station in the area of the node using
the stations callsign and adding the -1 SSID. The chances are great that a connect to the mailbox of the known station
will be made.
INITIAL CONNECTIONS TO THE NODE IN HOST MODE:
PARAMETER SETUP: After setting up the TNC2 hardware, connect a terminal to the RS232 port. Power up the TNC2
and make sure you see the TheNET X1 sign-on message. Then perform the following steps:
VERIFY THE NODE'S CALLSIGN: The callsign of the node (as burned into the EPROM) is displayed in the
TheNET X1 sign-on message. Make sure it is correct!
Host command lines begin with an ESC character (echoed as "* "). Valid host commands are: C, D, and P.
Esc-C CONNECT
The ESC-C command connects the host terminal to the node. When connected, the host terminal acts like a user that has
been uplinked to the node. All ordinary node commands (CONNECT, INFO, NODES, PARMS, RESET, SYSOP, and
USERS) may then be entered as information lines. However, the host connection automatically has sysop/manager
privileges, so using the SYSOP command is not necessary!
Esc -D DISCONNECT
The ESC-D command disconnects the host terminal from the node.
NOTE: For unattended operation, be sure to disconnect the host interface with ESC-D.
Esc -P password
The ESC-P command sets the "password string" used by the SYSOP command to validate the credentials of sysops. The
phrase may be up to 80 characters long (any excess is ignored), and may include spaces and control characters (except for
CR and LF). Upper- and lower-case letters are treated as distinct from one another in the password string.
Esc -P with no parameter displays the current password string.
Lines that don't start with an ESC are interpreted as information lines. If the host interface is connected, information lines
are sent across the connection; otherwise, they are discarded.
HOST INTERFACE MESSAGES:
The following messages may be displayed by the host interface:
CONNECTED to callsign
DISCONNECTED from callsign
CONNECT REQUEST from callsign
INVALID COMMAND
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 37
Chapter 16 Section II
GATEWAY INTERFACING & SETUP:
(NOTE: This modification does not apply to TNC2’s or clones manufactured after July 1990)! (see the illustration of this
modification in the illustrations at the back of this handbook).
The following modification is required for TNCs that will be used in dual-or multi-frequency TheNET X1 configurations.
Since it does not impair normal operation in any way, we recommend it for all TNCs to be used with TheNET X1. You may
want to upgrade to dual-frequency operation later.
To make this modification, connect one end of a wire to pin 23 of the RS232 connector. Connect the other end of the wire
to pins 1-2-3 of JMP9 (these three pins are already hooked together on the circuit board).
This modification allows the TheNET X1 firmware to be configured for multi-frequency operation by jumping RS232 pins
10 and 23 together in the TNC-to-TNC cable.
SET BAUD RATE SWITCHES:
Follow the switch-setting instructions in the TNC2 manual. I have performed extensive reliability testing of TheNET X1 at
HDLC and RS232 baud rates up to 9600; it runs reliably at these high baud rates even at slow CPU clock speed.
For dual- or multi-frequency operation, I suggest setting the RS232 speed at 9600 baud (or the highest RS-232 port baudrate
i.e.; 19,200 baud’s for MFJ-1270"C") it makes a big difference in cross-frequency performance!
WIRE TNC-TO-TERMINAL CABLE:
To connect a host terminal to the TNC2, almost any standard RS232 cable will do (as long as pins 9, 10, and 23 are not
used).
CONFIRM TNC/NODE OPERATION:
Install the X1 EPROM; If you have the add-on DEViation PC board, install it while the TNC is open. Connect a terminal
to the TNC, power it up, and make sure that you get a sign-on message and that the unit still appears OK. Note the STAtus
LED should glow at half brilliance when compared to the other LEDS.
If it doesn't:
(1) You have made an error.
(2) You have installed a bad EPROM.
(3) Your TNC won't run at the fast CPU clock speed.
(4) HAVE YOU INSTALLED THE WIRE FROM PIN ONE (1) OF THE X1 EPROM TO PIN 8
OF THE MODEM HEADER?
NOTE: Step number 4 does not apply when using MFJ-1270”C” REV 11 or above!
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 38
DUAL-OR MULTI-FREQUENCY OPERATION:
To install a dual or multi-frequency TheNET X1 node, you should follow the previously described steps for each TNC.
Make certain that each TNC has a different callsign (often, only the SSID suffix changes). Verify that each TNC is
functioning correctly as a single-frequency node before attempting to interconnect the TNCs.
For a dual-frequency node, simply connect the two TNCs together, using a special RS232 cable wired as shown in the
diagram. (Don't try to use the host-terminal cable - it won't work!) A node/gateway interface cable is constructed using the
following diagram:
This gateway interface cable enables node communications between two X-1J4 nodes, port to port. This configuration
allows the SNO to bridge from one frequency to another, or from one baud rate to another, OR BOTH. Set the DIP switches
to the same RS-232 port baud rate. The DIP switches are located at the rear of the MFJ-1270B and MFJ-1270C TNC’s.
Most applications at VHF have the 1200 baud node DIP switches 5 & 7 ON and all others OFF. On the 9600 baud
node/port set DIP switches 5 * 8 ON, all others OFF. On the late model MFJ-1270”CQ” Turbo TNC’s the RS-232 baud
rate can be set at 19,200 baud. Be sure that both TNC’s have this capability, otherwise, use the RS232 port setting of 9600
baud.
This drawing illustrates how a user TNC and a node can
be interfaced to one radio. Some node sysops utilize the
home QTH transceiver for both their Packet station TNC
and the node TNC.
The interface cable above illustrates how the TNC2
clones that use the 9 pin (DE 9) RS-232 comports are
connected for gateway. This gateway application can
enable communications between two different
frequencies, two different baudrates, or both.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 39
To interconnect three or more TNCs as a multi-frequency node-stack, you should build a diode-matrix coupler. A
schematic for a four-frequency coupler is shown below. It uses 24 diodes (1N4148, 1N914 or equivalent).
Configuring a multi-frequency TheNET X1 node for three or more frequencies is almost as easy as dual-frequency
operation. A TNC2 with TheNET X1J4 EPROM installed is used for each frequency. Once again, the TNCs are
interconnected via their RS232 ports. Interconnecting three or more TNCs requires nothing more elaborate than some
isolation diodes between the RS-232 ports.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 40
Chapter 17 Section II
X-1J/+ PARAMETERS
This section defines the function of the 26 parameters that the sysop can change remotely using the PARAMETERS command.
No. Description of Parameter LAN BackBone* Min Max
1. Max destination list entries 100 100 1 400
2. Minimum quality for auto-updates 86 141 0 255
3. HDLC (Radio, port 0) quality 86 141 0 255
4. RS232 (crosslink, port 1) quality 255 255 0 255
5. Initial value for obsolescence counter 9 9 0 255
6. minimum obsolescence count for broadcast 5 5 1 255
7. Auto-update broadcast interval 1800 900 0 65535
8. Network "time-to-live" initializer 32 32 0 255
9. Transport timeout (seconds) 180 180 5 600
10. Transport level 4 maximum tries 3 3 2 127
11. Transport level 4 ack delay(seconds) 2 2 1 60
12. Transport level 4 busy delay (seconds) 60 60 1 1000
13. Transport level 4 requested window size 4 4 1 127
14. Level 4 Congestion control threshold 4 4 1 127
15. No-activity timeout (Level 7 seconds) 1800 1800 0 65535
16. Persistence threshold(P/256) 64 255 0 255
17. Slot time (10ms increments) 10 1 0 127
18. Link level 2 T1 timeout "FRACK" (seconds) 4 1 1 15
19. Link level 2 TX window size "MAXFRAME" 2 3 1 7
20. Link level 2 maximum tries (0=try forever) 11 15 0 127
21. Link level 2 T2 timeout (10ms increments) 200 100 0 6000
22. Link level 2 T3 timeout (10ms increments) 0 0 0 65535
23. AX.25 level 2 digipeating (1=enabled) 0 0 0 1
24. Validate callsigns (1=enabled) 0 0 0 1
25. Station ID beacons (2=on, 1=active, 0=off) 2 1 0 2
26. CQ broadcasts (1=enabled, 0=disabled) 1 1 0 1
* Backbone at 9600 baud
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 41
The following definitions provide a short explanation of the purpose and use of the 26 parameters listed
in the above table.
Parameter 1
Max destination list entries (minimum=1, maximum=400)
Defines the maximum allowable number of destinations in the node's
routing table. Each destination consumes 32 bytes of RAM. The
sysop or network manager can use this parameter to limit the
amount of RAM that is allocated to the routing table, thus ensuring
that sufficient space remains for frame buffering.
Parameter 2
Worst quality for auto-updates (minimum=0, maximum=255)
Defines the poorest route quality that will be automatically added to
the node's routing table. The network manager can use this
parameter to limit the automatic routing update function to accept
only higher-quality routes.
In addition, the automatic update function can be disabled altogether
by setting this parameter to zero.
Parameter 3
Radio port 0 (HDLC) quality (minimum=0, maximum=255)
Defines the quality of the radio frequency connected to the node's
HDLC port. The network manager should set this parameter to an
appropriate quality value in accordance with the speed, reliability,
and congestion anticipated on the frequency. The default value of
192 is appropriate for a 1200-baud user-accessible frequency...if the
actual frequency quality is better (e.g., a UHF backbone frequency)
or worse (e.g., an HF link), the parameter value should
be changed accordingly.
Parameter 4
Comm port 1 (RS232) quality (minimum=0, maximum=255)
Defines the quality of the TNC-to-TNC interconnect frequency
connected to the node's RS232 port. The network manager should
set this parameter to an appropriate quality value in accordance with
the speed, reliability, and congestion anticipated on the frequency.
The default value of 255 is appropriate for a 9600-baud two-modem
interconnect cable...if the actual frequency quality is worse (e.g., a
three- or four-port interconnect, or a satellite link), the parameter
value should be changed accordingly.
Parameter 5
Obsolescence count initializer (minimum=0, maximum=255)
Defines the initial value given to the obsolescence count of a route
that has been newly added or updated by the node's automatic
routing table update mechanism. The obsolescence count of a route
is also reinitialized to this value whenever the route is actually used
successfully. The obsolescence count of a route is decremented
once each auto-update broadcast interval (see parameter 7 below).
However, such periodic decrementing of route obsolescence counts
can be disabled altogether by setting this parameter to zero.
Parameter 6
Obsolescence count minimum to be broadcast (minimum=1,
maximum=255)
Defines the minimum obsolescence count threshold below which a
route will not be included in the node's automatic routing broadcasts.
The purpose of this threshold is to prevent the node from
broadcasting "stale" routing information to other nodes. Under
normal circumstances, this parameter should be assigned a value
no greater than the value of parameter 5 (obsolescence count
initializer); if it is greater, the node's broadcasts
will include no destinations other than itself.
Parameter 7
Auto-update broadcast interval (seconds) (minimum=0,
maximum=65535)
Defines the number of seconds between automatic routing
broadcasts issued by the node. The default value of 3600 specifies
an hourly broadcast. In addition, broadcasts can be disabled
altogether by setting this parameter to zero.
Parameter 8
Network "time-to-live" initializer (minimum=0, maximum=255)
Defines the initial value of the "time-to-live" field in the Network
Header of all network-layer frames originated by this node. The
time-to-live field is decremented by each intermediate node that
relays the frame. If the time-to-live value ever reaches zero, the
frame is discarded. This protects the network against frames
persisting forever as the result of a routing loop. The value of this
parameter should be a bit larger than number of "hops" in the
longest legitimate route in the network.
Parameter 9
Transport timeout (seconds) (minimum=5, maximum=600)
Defines the number of seconds between transport-layer retries.
Parameter 10
Transport maximum tries (minimum=2, maximum=127)
Defines the maximum number of transport-layer tries attempted
before a circuit failure is reported.
Parameter 11
Transport acknowledge delay (seconds) (minimum=1,
maximum=60)
Defines the number of seconds' delay used by the transport layer
from the time it receives an information message until it sends an
information acknowledge message. The purpose of this delay is to
give the acknowledgment an opportunity to be "piggybacked" upon
an outgoing information message.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section II; TheNET X1J4 System Node Operators Handbook __ Page 42
Parameter 12
Transport busy delay (seconds) (minimum=1, maximum=1000)
Defines the maximum number of seconds that the transport layer will
remain "choked" as the result of an incoming message that has the
choke flag bit set. The purpose of this timeout is to prevent an
indefinite hang-up in the event that the "unchoke" message is lost.
Parameter 13
Transport requested window size (frames) (minimum=1,
maximum=127)
Defines the maximum number of incoming out-of-sequence
information messages that the transport layer will buffer while
waiting for the next expected information message to arrive. Also
defines the maximum number of outgoing information messages that
the transport layer will send without receiving acknowledgment.
Parameter 14
Congestion control threshold (frames) (minimum=1,
maximum=127)
Defines the maximum allowable backlog of messages that the
transport layer will buffer before it sends a choke message.
Also defines the maximum allowable backlog of frames that the link
layer will buffer before it sends an RNR control frame.
Parameter 15
No-activity timeout (seconds) (minimum=0, maximum=65535)
Defines the maximum number of seconds that a transport-layer
circuit or a link-layer connection can remain idle (i.e., no information
transfer in either direction) before it is automatically disconnected.
Parameter 16
P-persistence (p=/256) (minimum=0, maximum=255)
Together with slot time (parameter #17), defines the exponential
delay algorithm used by the node when keying up its transmitter.
When the node has something to transmit and the frequency is
clear, the node generates a random integer in the range 0 - 255. If
the random number is less than or equal to the P-persistence
parameter, the node keys up its transmitter immediately. Otherwise,
the node delays for one slot time, generates a new random number,
and repeats the procedure. The default value of 64 corresponds to a
probability of 0.25.
Parameter 17
Slot time (10ms increments) (minimum=0, maximum=127)
Together with P-persistence (parameter #16), defines the
exponential delay algorithm used by the node when keying up its
transmitter. The default value of 10 corresponds to a slot time of
100 milliseconds.
Parameter 18
Link T1 timeout "FRACK" (seconds) (minimum=1, maximum=15)
Defines the number of seconds between link-layer retries. When
digipeating is used, this value is multiplied by 2D+1, where D is the
number of digipeaters.
Parameter 19
Link transmit window size "MAXFRAME" (frames)
(minimum=1, max=7)
Defines the maximum number of outgoing information frames that
the link layer will send without receiving acknowledgment.
Parameter 20
Link maximum tries ( minimum=0, maximum=127)
Defines the maximum number of tries that the link layer will attempt
before reporting a link failure. If this parameter is set to zero, the link
layer will retry forever (not recommended).
Parameter 21
Link T2 timeout (10ms increments) (minimum=0, maximum=65535)
Defines the delay (measured in 10-millisecond increments) used by
the link layer from the time it receives an information frame until it
sends an acknowledgment
(RR, RNR, or REJ) control frame. The purpose of this delay is to
give the acknowledgment an opportunity to be "piggybacked" upon
an outgoing information frame.
Parameter 22
Link T3 timeout (10ms increments) (minimum=0, maximum=65535)
Defines the maximum no-activity period (measured in 10-millisecond
increments) permitted by the link layer before it issues a poll to make
sure the link is still intact. This timeout is also used to break linklayer
choke deadlocks. NOTE: This parameter is the same as the
CHECK command in many TNCs, and can be defaulted to 0 as a
means of reducing "Node QRM".
Parameter 23
AX.25 digipeating (1=enabled, 0=disabled), (minimum=0,
maximum=1)
Defines whether or not the node will perform AX.25 digipeating. The
default value of 1 causes digipeating to be enabled.
Parameter 24
Validate callsigns (1=enabled, 0=disabled) (minimum=0,
maximum=1)
Defines whether or not the node will perform validation checks on
amateur callsigns. The default value of 1 causes callsign validation
to be enabled. NOTE: If callsign validation is turned OFF (0), users
will experience long delays if they request connects to inactive nodes
before getting back a "Failure with" response.
Parameter 25
Station ID beacons (2=on, 1=conditional, 0=off) (minimum=0,
maximum=2)
Defines whether or not the node will broadcast station-identification
beacons. The default value of 2 causes station identification to be
broadcast every 10 minutes. The value of 1 causes station
identification to be broadcast only if the node has transmitted since
the last beacon. The value 0 disables station identification beacons
altogether.
Section 1; Packet Radio “The Basics” Section 2; Revised 9, 9, 2009 System Node Operator’s Handbook
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 43
NOTE: Many sysops set this parameter (#25) to 0 as a means to
reduce unnecessary node QRM on the frequency. The node sends
an ID's each time it sends a packet, so no legal requirement to have
ID's turned on.
As an example; In the MODES PARAMS, setting BEACON time to
600 will cause an ID by the X-IJ+ node every 10 minutes, or set it to
3600 and it will ID once each hour.
Parameter 26
CQ Broadcasts (1=0n, 0=off) (minimum=0,
maximum=1)
Defines whether or not the node will broadcast AX.25 UI-frames in
response to the CQ command. Even if such broadcasts are
disabled by setting this parameter to zero, the other features of the
CQ command continue to operate normally. The default value of 1
causes CQ broadcasts to be enabled.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
Section II; TheNET X1J4 System Node Operators Handbook __ Page 44
Chapter 18 Section II
The SEVENTEEN X1J4+ MODE COMMANDS AND DEFINITIONS
With the new X1-J version of theNET firmware, there also comes a set of 17 added command features. The
application of these 17 features can increase the effectiveness of your network when they are properly applied.
SEDAN MIN MAX DEFINITION
0 0 1 Host Control to enable HARDWARE HANDSHAKE; MODE FLAG in HOST MODE
Enables the use of the Esc C and Esc D commands when using the RS-232 port.
0 0 3600 CW ID repeat period in seconds.
0 Disables CW ID
6 4 10 CW ID speed (10 milliseconds per DOT)
3 0 3 Nodes broadcast enable flags: 0=None, 1=HDLC only, 2=RS-232 only, 3=Both ports.
3 = both ports if backbone access; 2=matrix; 1 if LAN or user port.
0 0 3 Crosslink select: 0=None, 1=HDLC, 2=KISS,+selectCopy, 3=KISS+ALLcopy
MATRIX mode for node stack use.
35 0 255 TX keyup delay (TXDELAY) in ten millisecond increments. 35 = 350 milliseconds; for
most transceivers, add 5 mSec for radios with relays nodes using external power amplifier.
0 0 1 Full Duplex enable. 0 if node is operated in simplex (normal) operation.
500 0 65535 RS-232, PORT 1, node broadcast period in seconds. 600 Updates nodes every 10 minutes.
0 0 3 Node broadcast algorithm flag; 0=off, 2=RS-232 port; 1 or 3 not used.
600 600 3600 Beacon interval in seconds.
600 Although beacons are enabled in PARAMS to ID only during or after use.
1 0 2 Connect redirect to BBS
0 Controls the use/action of the "C" command, and what it will do when issued.
27 0 127 Help messages enable flag, 8 bit in TALK mode & case sensitive. 19 Enables:
PLEASE WAIT. (1) + all sysop commands, (2) +Routes are: ALIAS:CALLSIGN
0 0 3 Hash node broadcast disable (1 bit per port) 3 will disable all #node broadcasting.
0 0 1 If set, will enable extra alias monitoring. 0=WILL NOT recognize BBSalias, DXalias,
HOSTalias, set to 1 on user port if BBSalias is set.
1 0 1 Enables automatic node reconnection after remote disconnect.
1 Enable on user accessed ports and #nodes; Disable on network step points (BBS..etc).
0 0 3 Slime trail control. Each bit controls a function; Bit 0 hides; Bit 1 causes slime to be ignored.
3 Set on non gateway port(s).
3 0 3 Digipeat control. Each Bit controls a function: Bit 0 Node refuses L2 uplink digis.
Bit 1 Node refuses digi downlinks.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
ILLUSTRATION SECTION Charts & Node Drawings TheNET X1J4 System Node Operators Handbook __ Page 45
APPENDIX “A”
FINAL NODE “CHECKLIST:”
When installing your 9600 baud nodes back on-line, and if you are using the small “rinky-dink” wall supply to power the
TNC/NODE, then check the power from the small wall type supply to be sure the supply is supplying over 14 volts. When
it is attached to the TNC, the voltage will drop to around 12 to 13 volts under load. If the supply is not delivering sufficient
power (voltage) to the TNC, the node will not perform properly and may not decode 9600 bauds. The same scenario
applies to the 1200 baud TNC and supply.
At my installations I chop the wall transformer wire off about 3 inches from the transformer/DC supply and attach it to the
12 volt DC power source that is used to power the radio for the node. Usually the wire with the small “white” tracer on it
is the positive lead, however, I’d ring it out with an ohm meter to be sure that the TNC center pin is connected to
“PLUS” (+)12 volts. The TNC needs less than half an ampere at 12 volts to make it work, so the load to the supply for the
radio should carry the extra load of the TNC well.
A low voltage problem may be experienced with the 9600 baud nodes more often than with the 1200 baud nodes. The
reason is; The 9600 baud node has the added load of the internal 9600 baud modem piggy back board. It adds to the supply
load with extra power requirement of the 9600 baud modem, and this is where I have some beef with the supplier.
CAVEATE ; In some recent mail and truck deliveries to my QTH, I have seen...(HEARD) rattling inside the TNC’s prior
to opening them. Seems the carriers uses them for base ball practice, and toss them hard enough to make the EPROM pop
out of socket U 23. This same scenario may be occurring with other deliveries of TNC and nodes to you. If you have any
problem at all, remove the (4) screws from the cover of the TNC/node and check all the IC’s to be sure they are inserted
securely into their respective socket.
ONCE YOUR TNC IS BUILT INTO A NODE; At the rear of the TNC/NODE is a set of 8 switches, called a inline 8 DIP
switch. DIP switch number 5 determines the baudrate of the RS232 port(s). Make sure both nodes have DIP switche(s)
number 5, in the ON position. Remember that some older TNC have the DIP switches UP =ON and DOWN=OFF. On
some of the later (most) “C” versions, the DIP switches are DOWN=ON and UP=OFF. The principal idea is to make sure
the TNC/NODEs are talking between the 1200 and 9600 baud NODE ports (GATEWAYING) properly.
DIP switch number 8 is “ON,” on the 9600 baud node. DIP number 7 is ON on the 1200 baud node. This is the switch
that determines the RADIO port speed.
So; here is what you should have:
the 1200 baud TNC/NODE; DIPs 5 & 7 are ON.. all others are OFF.
the 9600 baud TNC/NODE DIPs 5 & 8 are ON.. all others are OFF.
The following apply to both 1200 and 9600 baud VHF & UHF nodes:
Be sure you have the “UMBILICAL” cable is connected between the 1200 and 9600 baud RS232 ports.
The BLACK (HF/VHF) button on the rear of all MFJ-TNCs is OUT = OFF.
Make sure power is connected and ON; the RED button (Off/On) is ON = IN.
VISIT the SEDAN Packet Radio Networking Pages at: http://www.PacketRadio.com
BucK4ABT E-mail k4abt@PacketRadio.com
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
ILLUSTRATION SECTION Charts & Node Drawings TheNET X1J4 System Node Operators Handbook __ Page 46
APPENDIX “B”
LOCKING ROUTES AND SETTING “FIXED” NODE PATHS:
Configuring nodes and locking node routes and paths is an art. some say the art is
lost, but just ask any dedicated node sysop and you may discover a wealth of
knowledge and learn that the art of node configuration is “alive and well.” In this
section we will pass along some of this artistic node knowledge to the new and
aspiring node sysop.
NODE ROUTING BASICS, or “Choosing Your Node’s Neighbors”:
Nodes are dumb! Several system node operator’s (SNO’s) and Packet radio author’s in other publications have stated that
nodes are intellegent and should be left to attend to the automatic routing to and from all its neighbors. Nothing could be
further from the truth!
What happens when long ground wave and extended night-time “lifts” occur, then later the band changes or daylight
returns the VHF F1 & F2 layers to short-range propogation. The co-called intelligent group of network nodes has gathered
large node tables of nodes that can no longer be heard.
How quickly we learn that nodes are not so intellegent after all. This is where we begin our next level of node education.
Rather than to Lock OUT the Nodes you don't want, why not “lock in” the nodes that we do want as neighbor nodes.
Below, I have listed several ways to make the decision as to which nodes are neighbor nodes and which nodes we should
lock in! This kind of node housekeeping is called “locked routing” and thus removes the guess work that occurs when the
routing is left to the so-called “automatic routing” that is built into the node firmware.
When you first set up your LAN node on the network (not the backbone) or just after performing a “cold-start” (hard reset =
RESET *), set the first seven of the twenty six parameters to:
For 1200 baud nodes; P 100 81 81 255 9 5 1800 16 180 3 2 60 4 4 1800 64 10 4 2 10 200 0 0 0 2 1
For 9600 baud nodes; P 100 162 162 255 9 5 900 16 180 3 2 60 4 4 900 255 1 1 3 15 100 0 0 0 1 1
Let the node run this way for at least 24 hours. Once it has had ample time to gather a reliable routes table, PLEASE notice
that I said “reliable,” then look at the MHeard list (not the nodes or routes table) between the hours of 3:00 PM and 6:00
PM EST (I’ll explain the time of day bit in the next few paragraphs) also make a record of the routes table that is
displayed.
It is important to note which of the “nodes” in the MHeard list display the highest number of received repeat numbers. By
“received repeat number” I’m referencing the number of consecutive times the node has heard a node that is also listed in
the routes list. In the example below, I’ve indicated the nodes that have a higher number of NODES HEARD in the
Mheard list. These nodes become the first nodes that I lock into the routes table.
Here is a ROUTES list from node “EVA: WB4EDZ-7,” I’m Connected and I issue the “R”outes command; The node
returns:
EVA: WB4EDZ-7} Routes:
0 DFVA:N4OMC-1 60 *4
0 1200:K4ABT-8 60 *12
0 MTLAKE:KD4BNQ-7 60 *9
0 MVA:KC4SUE-7 60 *11
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
ILLUSTRATION SECTION Charts & Node Drawings TheNET X1J4 System Node Operators Handbook __ Page 47
After the initial 24 hours has passed, I pull an Mheard listing and read the numbers of consective received repeat numbers.
Any number that is 2 or above, I set in the node using the “routes lock” technique as shown in the example below:
R 0 [neighbor node] + [route quality]
The syntax of the ROUTES command is as follows:
· Route, Port, Callsign, + Quality
· Route = command
· Port = port number (0=radio & 1=RS-232)
· Callsign = Neighbornode Call/SSID
· + = plus sign
· Pathquality = 192 for LAN nodes or 224 for backbone nodes
Because I know that a very good route exists between node EVA:WB4EDZ-7 and node 1200:K4ABT-8, I lock the route
between EVA and 1200 in the follwoing manner;
R 0 K4ABT-8 + 192
As a rule, I don’t lock a route to a node that has a receive repeat number in the Mheard list below 6 unless that node route is
the only route in the table, or all the Mheard list show low receive repeat numbers for all the nodes shown. Even then I try
to use a common sense approach and note the proximity and connectivity of the nodes that I lock in.
When determining which node is truly a neighbor node, use a common sense approach. By this I mean; Look at the
number of times the neighbor node is shown in the Mheard list, and try to make the determination at a time of day when
propagation is low. I find this time to be between the hours of 2:30 PM and 5:00 PM eastern time.
1) Pick your real neighbor nodes from the routes table and lock them in at the recommended default quality
(192 for 2m, 224 for backbones.)
2) Where there is a “gateway” (2 nodes via RS-232) neighbor node lock these routes at 255. If you
are locking 3 nodes in a node stack (via RS-232 using a diode matrix), set each of the locked
routes at 245. When locking 4 nodes in a node stack, set each nodes route at 235. With 5 nodes,
set (lock) their routes at 225. DO NOT LOCK ANY NODES IN A NODE STACK BELOW 225.
Remember that 224 is the locked route quality for neighbor “backbone” nodes.
3) Reduce Parameter 3 (Default radio link quality given to new nodes) to a value equal to
Parameter 2 (Minimum quality to accept.)
NOTE: When locking RS-232 routes remember to use the 232 port number 1 (one) instead of the radio port number 0
(zero). Example: R “1” K4ABT-2 + 255
Here is how it works. Your real neighbors have the full quality value that you have assigned to them. Nothing changes
there, but by reducing parameter 3 to the same level as parameter 2, new nodes that are heard are given a quality on the
threshold of acceptance. This means that the new nodes in the broadcast will have their name and callsign entered into the
node table, but all its related node path information will have qualities too low to be shown or used. Only the node itself
will be allowed into the node table and nodes associated with the routing. Because the node is at the point of quality
acceptance, it won't expand to other nodes because its quality is degraded to a point that will fall below the minimum
quality of neighbor nodes.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
ILLUSTRATION SECTION Charts & Node Drawings TheNET X1J4 System Node Operators Handbook __ Page 48
The purpose for "Locking" the qualities of your real neighbor nodes, is to preserve their quality rating as true neighbors. If
one of your true neighbors goes down, it will be removed from the node table, however it will not be removed from the
“locked routes listing” unless you remove it.
To delete a locked route listing use the minus (-) sign where you used the plus sign (+) in the routes listing; Here is an
example of how I would remove the locked routes we entered earlier (quotation marks are mine):
R 0 K4ABT-8 “-” 192
It is viatlly important to the proper operation of the network that each SNO who locks in a route to a neighbor node not his
own, to notify the neighbor node SNO that he has down so. Ask the neighbor node SNO to lock his node in using the same
locked route quality as you have used. This insures good link quality and fewer retries between nodes. In many cases, it
prevents the familiar;
“RETRIED OUT AT NODE .....”
SUMMARY; SETTING NODE ROUTES:
The Node command may be used to make a manual entry in the node table. When this is done, it may also make an entry
in the routes table if necessary. The syntax of the command is :
NODE, Callsign, +, Ident, Quality, Count, Port, Neighbor
· callsign is the callsign of the destination node
· ident is the alias of the destination node
· Quality is the node quality for the entry
· Count is the obsolescence count to be given to the entry
· Port is the level 2 port ( 0 for radio, 1 for RS232 )
· Neighbour is the callsign of the neighbouring node to route through
So to make an entry that will never expire to ANODE:K4ABT-7 where the node is accessed directly on the radio port with a
quality of 192, enter
NODE K4ABT-7 + ANODE 192 0 0 K4ABT-7
If the same station is not heard directly but is accessed through node WB4EDZ-7 over the radio, and the entry will expire
when its obsolescence drops to zero from an initial count of 8, enter :
NODE K4ABT-7 + ANODE 192 8 0 WB4EDZ-7
An entry may be deleted by substituting - (minus) for + (plus).
IMPORTANT NOTE:
LOCK 1200 baud neighbor (radio (zero 0) port) nodes to each other at a value of 192
LOCK 9600 baud neighbor (radio (zero 0) port) nodes to each other at a value of 240
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
ILLUSTRATION SECTION Charts & Node Drawings TheNET X1J4 System Node Operators Handbook __ Page 49
APPENDIX “C”
The MFJ-52B DEViation and ADC meter for the X-1J4 NODE
The following addendum of this handbook is excerpted from the X1J4 overview documentation by Dave Roberts
and Neville Pattinson. The purpose of this addendum is to give the X1J4 sysop a jump-start to configure the
addition of the MFJ-52A PC Board in the X1J4 node. For a much more detailed set of X1J4 documentation, print
the OVERVIEW.TXT file from the original X1J/2 disk.
© METER
© ADC (S meter)
© ADC1 (Temperature)
© ADC2 Voltage)
METER COMMAND:
This command's syntax is similar to the PARMS command, and includes the new syntax as described in
the X1J4 overview guide, section 3.32.
It allows the following parameters to be controlled. Note that the parameter list differs from TheNet X-1J,
where the first ( and only ) parameter was the deviation meter scaling factor.
1 The meter mode flags
2 The deviation meter scaling factor
3 The signal strength meter noise floor value
4 The S meter display format multiplier
5 The dBm meter display format multiplier
6 The dBm noise floor value
7 The voltmeter channel 1 multiplier
8 The voltmeter channel 2 multiplier
9 The voltmeter channel 1 offset value
10 The voltmeter channel 2 offset value
IMPORTANT NOTE ! If you are NOT using the MFJ-52B deviation, temperature, volt, and S meter add-on PC
board, then set the METER command to:
ME 0 0 0 0 0 0 0 0 0 0
THE METER MODE FLAGS
Each bit of this parameter controls a different aspect of the meters as shown below
BIT If set, then ....
0 The deviation meter is enabled
1 The signal strength meter is enabled
2 The signal strength is shown as S points rather than dBm
3 ADC channel 3 is enabled ( voltmeter channel 1 )
4 ADC channel 4 is enabled ( voltmeter channel 2 )
5 Voltmeter channel 1 divisor is 1000 rather than 100
6 Voltmeter channel 2 divisor is 1000 rather than 100
7 Voltmeter channel 1 displays fine resolution rather than integers
8 Voltmeter channel 2 displays fine resolution rather than integers
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
ILLUSTRATION SECTION Charts & Node Drawings TheNET X1J4 System Node Operators Handbook __ Page 50
THE DEVIATION METER SCALING FACTOR
This is the parameter previously described in section 3.31 of the overview guide. It scales the deviation
meter display. One change however from X-1J. Setting it to zero does not disable the deviation meter -
bit 0 of the meter mode word as described above controls whether it is enabled.
When set to a value in the range 1 - 255, the meter is enabled and the value is used as a scaling factor.
The ADC is an 8 bit device, so it will give a response in the range 0 - 255, corresponding to an ADC input
voltage in the range 0 - 3 volts DC. If optimally configured, this corresponds to the maximum audio level
possible for the given receiver discriminator.
The ADC reading ( 0 - 255 ) is multiplied by the meter parameter value ( 1 - 255 ) to give an answer in
the range 0 to 65 KHz ( approx. ). This is the value displayed in the MHeard list.
Hence, if, for example, a DC voltage of 2 volts at the input to the ADC corresponds to 3.4 KHz deviation,
the ADC reading will be 171 ( +- a few ) and the Meter parameter will need setting to 20 ( i.e. to 3400 /
171 ).
If the ADC reading is 254 or higher, then in order to indicate an overrange, the symbol '>' will precede
the corresponding deviation entry in the heard list.
The signal strength meter noise floor value
This parameter sets the 'no signal' offset applied to input readings from the signal strength meter. It is
subtracted from the count read from the ADC to give a reading based on a no signal value of zero. If the
no signal ( noise ) reading is, for example 0.65V, corresponding to an ADC count of 256 * 0.65 / 3 or 54,
then 54 is subtracted from each ADC signal strength reading to give an integer from 0 to 201 for an input
reading between 54 and 255.
The S meter display format multiplier
This parameter operates in a similar manner to the dBm multiplier ( section 3.31.5 ) but having divided
the intermediate result by 256, that value is displayed as an integer in the range 0 to 9 preceded by the
letter 'S'. If the value exceeds 9, it is displayed as 'S9+'. If the dBm multiplier has been set up correctly,
then set this parameter to the dBm multiplier divided by the number of dB per S point.
The dBm meter display format multiplier
This parameter is used to convert an ADC reading for the signal strength meter into a dB count. The
ADC reading is converted into a count from 0 to n, according to the description contained in section
3.31.3. It is then multiplied by this parameter and divided by 256. When added to the dBm noise floor
value ( section 3.31.6 ), this gives the displayed dBm value in the heard list.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
ILLUSTRATION SECTION Charts & Node Drawings TheNET X1J4 System Node Operators Handbook __ Page 51
The dBm noise floor value
This is the noise floor ( dBm ) reading that corresponds to the zero count in section 3.31.3. It is entered
as a positive count corresponding to a negative value. For example, if the zero point in the example of
section 3.31.3 is -113 dBm, the noise floor value entered is 113.
The voltmeter channel 1 multiplier (Temperature sensor)
This is the multiplier that controls voltmeter channel 1 ( ADC channel 3 ). It is set as described in section
3.34 of the X1J4 overview doc.
The voltmeter channel 2 multiplier
This is the multiplier that controls voltmeter channel 2 ( ADC channel 4 ). It is set as described in section
3.34 of the X1J4 overview doc.
The voltmeter channel 1 offset value
This is the value subtracted from the ADC reading before it is multiplied by the multiplier parameter. It is
described more fully in section 3.34 of the X1J4 overview doc.
The voltmeter channel 2 offset value
This is the value subtracted from the ADC reading before it is multiplied by the multiplier parameter. It is
described more fully in section 3.34 of the X1J4 overview doc.
IMPORTANT NOTE (again)!
If you are NOT using the MFJ-52B deviation, temperature, volt, and S meter add-on PC board, then set the
METER command to:
ME 0 0 0 0 0 0 0 0 0 0
No further input for the MEter command is necessary.
Here is an example of the Meter BIT settings of my ADC/MFJ-52B at K4ABT-7:
ME 351 96 50 10 50 120 106 62 32
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
ILLUSTRATION SECTION Charts & Node Drawings TheNET X1J4 System Node Operators Handbook __ Page 52
APPENDIX “D”
The Access Connect Limiting (ACL) command is a useful feature of the X-1J+ nodes. It enables the sysop to set node
backbones to allow only access by other backbone nodes and the sysop’s call(s).
In other instances, the ACL feature may be used to restrain an offending station to a node, or network of nodes by invoking
the feature of the X-1J+ node.
At some point in time we are all faced with a situation that calls for action on the part of the X-1J node sysop to invoke the
Access Connect Limiting (ACL) command. Please try to resolve any conflict with any network or node offender before
turning to the use of the ACL to exclude his or her access to the node or network.
In one case, a BBS sysop who had just moved to the area from a distant State was hoping to establish another BBS so the
area users would have a means to handle local traffic. He began operation of his node on 145.770 the nationwide
Emergency and keyboard to keyboard frequency. He was informed of the purpose of the frequency of 145.770 MHz, and
without additional dialog, he moved his BBS to another LAN frequency.
In another case, an unscrupulous operator set up operation on the frequency and proceeded to use the system for DX
spotting during an ongoing weather-watch activity. After all else had failed did we invoke the ACL feature and excluded
his node, callsigns, and SSID’s from the network.
This won't be the last time this problem surfaces in any network.
TACT & DIPLOMACY:
If you find that you as a sysop are confronted with a similar situation, try first to remedy the situation with a kindness
approach. A bit of tact and diplomacy goes a long way.
If it appears that no reconcilable solution can be found then let the rest of the sysops know of your plight.
A deluge of letters from the sysops to the offender may help change his/her attitude toward your network. Where
emergency communications are concerned an act of malicious mischief is frowned on by both the ARRL and the FCC.
If all efforts for resolve fail, then remember that we have the ACL feature in the X1J+ code. ACL is a feature that we don't
care to implement (and please don’t abuse it) unless it is absolutely your last recourse.
The ACL feature is activated by first setting the mask ON. To do so, enter the sysops command mode using your node
password. To set the “mask”; Send the following command to the node:
ACL & 127
Your next entry is to set (ACL) the offending call sign:
ACL [offending CALL sign] + 127
The offending node or station is history. The "127" sees to it that the call and/or any SSID of the offending call is denied
access to your node.
To remove the call from the ACL list, use the minus sign in the ACL string instead of the Plus (+) sign i.e.
ACL [CALL] - 127
The user of the call sign now has all node privileges restored.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
ILLUSTRATION SECTION Charts & Node Drawings TheNET X1J4 System Node Operators Handbook __ Page 53
This modification is for the older, pre 1990, (no suffix), MJF-1270. Most MFJ-1270”B” versions and all “C” versions are
already configured with this feature. To perform this modification, connect one end of a wire to pin 23 of the RS232
connector. Connect the other end of the wire to pins 1-2-3 of JMP9 (these three pins are already connected together on the
circuit board). This modification allows the TheNET X1 firmware to be configured for multi-frequency operation by
jumpering RS232 pins 10 and 23 together in the TNC-to-TNC cable.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
ILLUSTRATION SECTION Charts & Node Drawings TheNET X1J4 System Node Operators Handbook __ Page 54
This drawing illustrates how the X-1J4 EPROM is installed and connected in the MFJ-1270B TNC. Note that PIN one of
the EPROM is not inserted into the socket at U23. Pin one (1) also has a wire attached to it and is routed to pin 8 of the
MoDem header. This mod also illustrates how the MFJ-1270”B” version is configured with the MFJ-52B DEViation meter
installation.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
ILLUSTRATION SECTION Charts & Node Drawings TheNET X1J4 System Node Operators Handbook __ Page 55
Another overview of how the X-1J4 EPROM is installed and connected in the MFJ-1270B and earlier. See following pages
for the installation of the EPROM in MFJ-1270”C” Rev 10. The MFJ-1270”C” REV 11 and later follows the REV 10
illustration.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
ILLUSTRATION SECTION Charts & Node Drawings TheNET X1J4 System Node Operators Handbook __ Page 56
An overview of how the X-1J4 EPROM is installed and connected in the MFJ-1270”C” Rev 10 . See next drawing for the
installation of the EPROM in MFJ-1270”C” Rev 11 and later.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
ILLUSTRATION SECTION Charts & Node Drawings TheNET X1J4 System Node Operators Handbook __ Page 57
In this drawing I have outlined how the X-1J4 EPROM is installed and connected in the MFJ-1270”C” Rev 11(latest)
version. A detailed list of procedures to transform the MFJ-1270C REV 11 into a node are on the following page.
The Packet Radio “2 N 1” Handbook by Buck Rogers K4ABT
Section 1; Packet Radio “The Basics” Section 2; The X1J4 System Node Operator’s (SNO) Handbook
ILLUSTRATION SECTION Charts & Node Drawings TheNET X1J4 System Node Operators Handbook __ Page 58
The following steps outline the procedures to transform the MFJ-1270C REV 11 (shown on the previous page) into an X1J4 node
1. Remove jumper from all pins of JMP 9. Jumper may be used later in this TNC to X-1J2 node modification.
2. Remove IC U40. After the modification is complete, place U40 into a plastic wrapper and tape inside the front faceplate
for use if the node is ever returned to normal TNC service.
3. Remove jumper from JMP 15. ADD A JUMPER at JMP 16. ADD JUMPER at JMP 21.
4. Cut trace at JMP “X” Notice that tiny traces are close to JMP X: DO NOT CUT any other trace. Cut ONLY the trace
between pads of JMP X. Use extreme caution when cutting. This step is optional and may not be necessary unless you
are concerned with the node hearing itself in RF rich environments.
5. If TNC is to be used as a GATEWAY between two frequencies or baud rates, insure that R14 & R15 are installed. If
they are not, remove the PC board and add R14 and R15. R14 and R15 are 100 ohms @ 1/4 watt each.
6. To remove the PC board, remove the front face-plate (2 screws), then remove the screw which attaches Q3 (regulator)
heat-sink to the front of the TNC. Next remove the four (4) screws which hold the PC board in place. The locations of
the screws are shown in the drawing as a circled “X” symbol.
7. Remove the EPROM at IC U23. CAREFULLY install the new X-1J4 EPROM into socket at U23. BE SURE ALL
PINS ARE INSERTED INTO THE SOCKET. The number 1 pin is NOT left out of socket pin 1 as with earlier
revisions of this TNC. This modification applies to MFJ-1270C "Rev 11" and later versions.
The TINY-2 Mark II is a TNC-2 Clone comes ready
to operate 300 and 1200 bauds. An internal MoDem
disconnect header to enable faster baud rates.
The TINY-2 is TheNET X-1J4 EPROM compatible.
See photo below:

The Home of Packet Radio
Our thanks to Ron Raikes WA8DED (NetROM/Software 2000), Hans Georg Giese DF2AU
(TheNET/NORD-LINK), Dave Roberts G8KBB, Neville Pattison G0JVU (X-1J+TheNET/
Suffolk Data Group) and Bill Beech NJ7P for the implementation of this outstanding
networking tool. The foundation for the X-1J+ code comes from the NORD-LINK Group. To
these authors we wish to express our gratitude.
Buck Rogers K4ABT
TheNet X-1J4 and TheNet Plus is a derivative of NORD-LINK's TheNet 1.01 by G8KBB & G0JVU.
The software is for use in Amateur Radio only. It may be freely copied for such use provided its source is acknowledged.
l TheNet 1.01 Software © NORD-LINK
l X-1J Software © Dave Roberts, G8KBB, 1993-97 - Hardware ©
l Neville Pattinson, G0JVU, 1993-97
l Bill Beech NJ7P, TheNet Plus
X-1J4 "TheNET" NODE PARAMS
Click on a PARAMETER number to jump to the definition for that parameter. For "LOCKED" node applications and
information, click on the blue "1200 Baud or 9600 Baud" headers. The settings shown for the 1200 baud user port and the
9600 baud backbone are the node settings and are shown as example only.
The hierarchy shown allows a "natural" migration of data packets from the user port onto the backbone. This is an
exception and not the rule. Other networks may use a different concept and the author does not endorse any partictular
routing scheme as "too many cooks have already spoiled the broth" by trying to make network configuration complicated.
It is true that a measure of "node" common-sense, should be applied when setting up a network.
Parm
#
Purpose Default Minimum Maximum
1200
Baud
9600
Baud
1 Size of destination
node table
100 1 400 100 100
2 Minimum auto
update quality 60 0 255 60 143
3 HDLC (radio port)
quality 60 0 255 60 143
4 RS-232 (Crosslink)
port quality 255 0 255 255 255
5 Initial obsolescence
count 9 0 255 9 9
6
Minimum
Obsolescence to
broadcast
5 0 255 5 5
file:////your-4dacd0ea75/zip-100 (n)/0pro/x1j4pram.htm (1 of 7)11/13/2006 7:56:13 AM
The Home of Packet Radio
7 Nodes broadcast
interval (seconds) 1800 0 65535 1800 900
8 Initial time-to-live 16 0 255 16 16
9 Transport FRACK
timeout (seconds) 180 5 600 220 220
10 Transport RETRY
counter 3 1 127 3 3
11 Transport (L4) ack
delay (seconds) 2 1 60 2 2
12 Transport busy
delay (seconds) 60 1 1000 60 60
13 Transport window
size (frames) 4 1 127 4 4
14 Transport overfill
limit (frames) 4 1 127 4 4
15 No-Activity timeout
(seconds) 900 0 65535 900 900
16 Persistance (n/256) 64 0 255 64 255
17 Slottime (x 10ms) 10 0 127 10 1
18 FRACK (T1) time 5 1 15 5 1
19 AX.25 windowsize
(L2 MAXFRAME) 2 1 7 3 3
20 AX.25 (L2) retries 10 1 127 10 15
21 ACK (T2) time (L2
RESPTIME) 100 0 65535 200 100
22 Active check (T3)
(x10ms) 0 0 65535 0 0
23 Digipeat 0 0 1 0 0
24 Callsign validation 1 0 1 0 1
25 Beacon mode
control 2 0 2 2 2
26 CQ broadcasts 1 0 1 1 0
X-1J4 PARAMETER DEFINITIONS
Parameter 1 Max destination node list size; (default=100, minimum=1, maximum=400)
Defines the maximum number destination nodes allowed in the node's routing table. Each destination consumes 32
bytes of RAM. The system node operator (SNO) can use this parameter to limit the amount of RAM that is
allocated to the routing table, thus ensuring that sufficient space remains for other node buffers. Normally there are
720 free buffers in the X-1J4 node at startup.
file:////your-4dacd0ea75/zip-100 (n)/0pro/x1j4pram.htm (2 of 7)11/13/2006 7:56:13 AM
The Home of Packet Radio
Parameter 2 Worst quality for auto-update; ( default=60, minimum=0, maximum=255)
Defines the poorest route quality that can be added to the node's automatic routing table. The system node operator
(SNO) can use this parameter to limit the automatic routing update function to accept only higher-quality routes. In
addition, the automatic update function can be disabled altogether by setting this parameter to zero.
Parameter 3 Channel 0 (Radio Port) quality; (default=60, minimum=0, maximum=255)
Defines the quality of the radio channel connected to the node's HDLC port. The system node operator (SNO)
should set this parameter to an appropriate quality value in accordance with the speed, reliability, and congestion
anticipated on the channel. The default value of 192 is appropriate for a 1200-baud user-accessible frequency.
Parameter 4 Channel 1 (RS232 Port) quality; ( default=255, minimum=0, maximum=255)
Defines the quality of the TNC-to-TNC interconnect channel connected to the node's RS232 port. The system node
operator (SNO) should set this parameter to an appropriate quality value in accordance with the speed, reliability,
and congestion anticipated on the channel. The default value of 255 is appropriate for a 9600-baud two-modem
interconnect cabled gateway.
Parameter 5 Obsolescence count initializer; ( default=9, minimum=0, maximum=255)
Defines the initial value given to the obsolescence counter of a route that has been recently added or updated by the
node's automatic routing table. The obsolescence count of a route is also reinitialized to this value whenever the
route is successfully used or when the period set to the noted value shown in the STATS table of the X-1J4 node.
The obsolescence count of a route is decremented once each auto-update broadcast interval (see parameter 7).
Periodic decrementing of route obsolescence counts can be disabled altogether by setting this parameter to zero (0).
Parameter 6 Obsolescence count minimum to be broadcast ( default=5, minimum=1, maximum=255)
In the X-1J4 node, this parameter defines the minimum obsolescence count threshhold below which a route will not
be included in the node's automatic routing broadcasts. The purpose of this threshhold is to prevent the node from
broadcasting out dated routing information to other nodes. Under normal circumstances this parameter should be
assigned a value no greater than the value of parameter 5. If parameter 5 is greater, the X-1J4 node's broadcasts will
NOT include destination nodes other than itself.
Parameter 7 Auto-update broadcast interval (seconds) ( default=1800, minimum=0, maximum=65535)
Defines the number of seconds between automatic routing broadcasts issued by the node. The default value of 3600
specifies an hourly broadcast. X-1J4 node broadcasts can be disabled altogether by setting this parameter to zero
(0).
Parameter 8 Network TIME TO LIVE initializer ( default=16, minimum=0, maximum=255)
Defines the initial value of the time-to-live; field in the Network Header of all network-layer frames originated by
this node. The time-to-live field is decremented by each intermediate node that relays the frame. If the time-to-live
value ever reaches zero, the frame is discarded. This protects the network against frames living forever as the result
of a routing loop.
Parameter 9 Transport timeout (seconds) ( default=180, minimum=5, maximum=600)
Defines the number of seconds between transport-layer retries.
Parameter 10 Transport maximum tries ( default=3, minimum=2, maximum=127)
Defines the maximum number of transport-layer tries attempted before a circuit failure is reported.
Parameter 11 Transport acknowledge delay (seconds) ( default=2, minimum=1, maximum=60)
Defines the number of seconds' delay used by the transport layer from the time it receives an information message
until it sends an information-acknowledge message. The purpose of this delay is to give the acknowledgement an
opportunity to be added to another outgoing information frame or packet.
file:////your-4dacd0ea75/zip-100 (n)/0pro/x1j4pram.htm (3 of 7)11/13/2006 7:56:13 AM
The Home of Packet Radio
Parameter 12 Transport busy delay (seconds) ( default=60, minimum=1, maximum=1000)
Defines the maximum number of seconds that the transport layer will remain choked; as the result of an incoming
message that has the choke flag bit set. The purpose of this timeout is to prevent an infinite hangup in the event that
the unchoke message is lost.
Parameter 13 Transport requested window size (frames) ( default=4, minimum=1, maximum=127)
Defines the maximum number of incoming, out-of-sequence, information messages that the transport layer will
buffer while waiting for the next expected information message to arrive. Also defines the maximum number of
outgoing information messages that the transport layer will send without receiving acknowledgement.
Parameter 14 Congestion control threshhold (frames) ( default=4, minimum=1, maximum=127)
Defines the maximum allowable backlog of messages that the transport layer will buffer before it sends a choke
message. Also defines the maximum allowable backlog of frames that the link layer will buffer before it sends an
receive-not-ready (RNR) control frame.
Parameter 15 No-activity timeout (seconds) (default=900, minimum=0, maximum=65535)
Defines the maximum number of seconds that a transport-layer circuit or a link-layer connection can remain idle (i.
e., no information transfer in either direction) before it is automatically disconnected.
Parameter 16 P-persistence (p=/256) ( default=64, minimum=0, maximum=255)
Together with slot time (parameter #17), defines the exponential delay algorithm used by the node when keying up
its transmitter. When the node has something to transmit and the channel is clear, the node generates a random
integer in the range 0 - 255. If the random number is less than or equal to the P-persistence parameter, the node
keys up its transmitter immediately. Otherwise, the node delays for one slot time, generates a new random number,
and repeats the procedure.
Parameter 17 Slot time (10ms increments) ( default=10, minimum=0, maximum=127)
Together with P-persistence (parameter #16), defines the exponential delay algorithm used by the node when
keying up its transmitter. The default value of 10 corresponds to a slot time of 100 milliseconds. NOTE to the
wise... and maybe the "unwise," setting this parameter to 0 (zero) may make the node respond fast! Maybe too
fast.
Parameter 18 Link T1 timeout frack; (seconds) ( default=5, minimum=1, maximum=15)
Defines the number of seconds between link-layer retries. When digipeating is used, this value is multiplied by 2 x
D+1, where D is the number of digipeaters.
Parameter 19 Link transmit window size maxframe; ( default=3, minimum=1, maximum=7)
Defines the maximum number of outgoing information frames that the link layer will send without receiving
acknowledgement.
Parameter 20 Link maximum tries ( default=10, minimum=0, maximum=127)
Defines the maximum number of tries that the link layer will attempt before reporting a link failure. If this
parameter is set to zero (0), the link layer will retry forever (we recommend that this parameter is NEVER set to
zero (0) ).
Parameter 21 Link T2 timeout (10ms increments) (default=200, minimum=0, maximum=65535)
Defines the delay (measured in 10-millisecond increments) used by the link layer from the time it receives an
information frame until it sends an acknowledgement (RR, RNR, or REJ) control frame. The purpose of this delay
is to give the acknowledgement an opportunity to be attached to another outgoing information frame.
Parameter 22 Link T3 timeout (10ms increments) (default=0, minimum=0, maximum=65535)
file:////your-4dacd0ea75/zip-100 (n)/0pro/x1j4pram.htm (4 of 7)11/13/2006 7:56:13 AM
The Home of Packet Radio
Defines the maximum no-activity period (measured in 10-millisecond increments) permitted by the link layer
before it issues a poll to make sure the link is still intact. This timeout is also used to break link-layer choke
deadlocks. NOTE: This parameter is the same as CHECK, and can be defaulted to 0 as a means of reducing node
QRM.
Parameter 23 AX.25 digipeating (1=enabled, 0=disabled) (default=0, minimum=0, maximum=1)
Defines whether or not the node will perform AX.25 digipeating. The default value of 1 causes digipeating to be
enabled.
Parameter 24 Validate callsigns (1=enabled, 0=disabled) (default=1, minimum=0, maximum=1)
Defines whether or not the node will perform validation checks on amateur callsigns. The default value of 1 causes
callsign validation to be enabled.
NOTE; If callsign validation is turned OFF (0), users will experience long delays if they request connects to
inactive nodes before getting back a FAILURE WITH, response.
Parameter 25 Station ID beacons (2=on, 1=conditional, 0=off) (default=2, minimum=0, maximum=2)
Defines whether or not the node will broadcast station-identification beacons. The default value of 2 causes station
identification to be broadcast every 10 minutes. The value of 1 causes station identification to be broadcast only if
the node has transmitted since the last beacon. A zero (0) will disable station identification.
NOTE; Many sysops set this parameter to 0 as a means to reduce unnecessary node QRM on the channel. The X-
1J4 node ID's itself each time it sends a packet, so no legal requirement to have ID's turned on.
Parameter 26 CQ Broadcasts (1=0n, 0=off) (default=1, minimum=0, maximum=1)
Defines whether or not the node will broadcast AX.25 UI-frames in response to the CQ command. Even if such
broadcasts are disabled by setting this parameter to zero, the other features of the CQ command continue to operate
normally. The default value of 1 enables CQ broadcasts. NOTE; When a station connected to an X-1J4 node
through several distant nodes issues a UI QRA command, the distant node will poll stations that have the QRA
feature for an ID. After about 40 seconds, the station that sent the polling (UI QRA) can issue the Mheard
command and receive a list of the station that identified in the area of the distant X-1J4 node that was polled.
MODE SETTINGS FOR THE X-1J4 NODES
MODE
No.
Function
1200
BAUD
NODE/
PORT
9600
BAUD
NODE/
PORT
1 Host mode control (RS-232 port,hardware handshake). 0 0
2 CWID repeat period (seconds) 0 0
3 CWID keyer speed (10 milliseconds per dot) 6 6
4 Nodes port broadcasts (RS232 and/or HDLC) 3 3
5 RS-232 crosslink protocol 0 0
6
Transmit keyup delay/TXDelay X 10 milliseconds (*Depends on radio PTT to full
output power, time.)
35 20 *
7 Full duplex (0=OFF 1=ON) 0 0
8 Crosslink node broadcast interval (seconds) 450 600
9 Node broadcast algorithm port control flag 2 2
file:////your-4dacd0ea75/zip-100 (n)/0pro/x1j4pram.htm (5 of 7)11/13/2006 7:56:13 AM
The Home of Packet Radio
10 Beacon interval (seconds) 3600 3600
11 Connect redirect flag 1 1
12 User help message control flags 27 27
13 Hash node broadcast port control (1 bit per port) 0 0
14 Enable/Disable extra alias monitoring 0 0
15 Enable auto-reconnect to node after "bye" from mailbox or neighbor node. 1 1
16 Control of slime trails (Bit 0 hides slime trails) 0 0
17 Digipeat control (Disable L2 Uplink & Downlinks) 3 3
LOCKING ROUTES, (when using the parameters shown above).
1200 Bauds
When locking (radio port = 0) paths between 1200 baud neighbor nodes, use a
"locked path" quality of 192. Be sure both neighbor nodes are locked
to each other and use the same value (192).
Locked route example: R 0 [NeighborNodecall&SSID] + [port quality (192)
9600 Bauds
When locking (radio port= 0) paths between 9600 baud neighbor nodes, use a
"locked path" quality of 240. Be sure both neighbor nodes are locked
to each other and use the same value (240).
Locked route example: R 0 [NeighborNodecall&SSID] + [port quality (240)
LOCKING (RS232) GATEWAYS
When locking gateway (1200-9600) neighbor nodes (nodes connected via port 1/RS232)
umbilical, use a route quality of 255.
file:////your-4dacd0ea75/zip-100 (n)/0pro/x1j4pram.htm (6 of 7)11/13/2006 7:56:13 AM
The Home of Packet Radio
Example: R [neighbor nodecall] + [port quality (255)]
NOTE: Port 0 (zero)=radio. Port 1 (one)=RS-232 port.
To remove a locked route, substitute the - (minus) sign for the + (plus) sign.
Feedback:
WebMaster, Buck Rogers K4ABT "
You are Visitor
since 7 July 1996.
Backet to the "Packet Users Notebook" home page
© G. E. "Buck" Rogers Sr.
file:////your-4dacd0ea75/zip-100 (n)/0pro/x1j4pram.htm (7 of 7)11/13/2006 7:56:13 AM

No comments: