This FAQ archived and provided free as a courtesy by The Providence Cooperative http://www.providenceco-op.com ======================================================================= Survival Communications FAQ Version 1.12 DISCLAIMER: The authors and editors of this FAQ panel assume no legal responsibility for any errors in or misuse of this information, and are not to be held legally liable or responsible for any death, injury, loss of property, or other negative consequences resulting from use, misuse, or abuse of this information. This document was based upon an earlier FAQ written by another m.s lurker, and has received many contributions from m.s members who wished not to be named here. Any comments should be sent to me at medintz@idir.net, and will be acted on or forwarded to the other authors as appropriate. This document is being archived at: http://www.grapevine.net/~medintz/surv_faq/comfaq112.txt and http://www.providenceco-op.com Archiving or re-distribution is permitted only according to the terms of the document http://www.grapevine.net/~medintz/disclaim.txt. In general, redistribution, use, or storage is approved, but there are certain stipulations and exceptions in that document that must be obeyed. This document is a work in progress. Suggestions, comments, and recommendations are always welcomed, and will be acted on or forwarded as appropriate. Further information on radio may be gathered from 'The ARRL Handbook' and the 'ARRL Operating Manual', published by the American Radio Relay League(http://www.arrl.org) A topic as broad as communications can never been completely covered, especially in what should be a terse and matter-of-fact FAQ. We'll start out with the most general description we can provide, and get more specific deeper in the document. WHAT IS COMMUNICATION ? The first step in understanding communications in the context of survival is understanding of the fundamentals of communication itself. Communication is a very complex topic, as difficult to completely define as truth, beauty, or time; however, in an attempt to cut to the chase and make our life simple, we'll start with two definitions: COMMUNICATION is the successful transfer of information from one person to another person or entity. COMMUNICATION SYSTEMS are comprised of equipment, methods and techniques of supporting information transfer, enabling communication to take place between two people. (Please note that these definitions are cheap outs, since we haven't defined what we mean by information, but you get it, right? Note that we re also limiting things by requiring at least one person in to loop, to reduce the scope of this document.) What Happens When We Communicate? In order for any communication to take place, there are three major requirements that must satisfied. REQUIREMENT ONE: There must be a sender and a receiver. For most survival purposes, this means a person trying to send a message and a person looking for a message sent to them. REQUIREMENT TWO: The sender and receiver must understand how the message is to be conveyed, and must understand the message itself. In the survival context, this means that both people trying to communicate understand how their communication system works (how to operate the communications equipment, that one or two lamps have different meanings, how to look up a word in a dictionary) and that they understand the message (the message in clear and in a common language, that one lamp means that the British are coming by land and two lamps means by sea.) REQUIREMENT THREE: the communication system must be capable of delivering the message. (There's not so much fog the lamps can't be seen, or that the radios are within range and working properly. THE ONE RULE OF COMMUNICATIONS: To communicate, the sender creates a message that both he and the receiver should understand. Then, using a common system that is capable of delivering the message, the sender transmits the message to the receiver, who understands the message sent. SURVIVAL IMPLICATIONS Failure to communicate is always the result of a failure to meet the requirements. A few specific examples: The first requirement being that there is someone trying to send a message and someone expecting to receive it may at first seem obvious, however in practice it is probably the most violated requirement of communications in a survival context, providing the violator with a false sense of security until they need to communicate. For some reason, somebody buys a CB and thinks they can be in the middle of nowhere, call for help on channel 9, and Air Rescue magically appears to come in and save them. Yup, it's a long day in hell when this happens. It's not just CB owners, either: this requirement gets violated by amateur radio operators (I'll just call for help on the repeater except they left the directory home and their rig doesn't provide the right sub-audible tones, or the guy that just answered your CQ or SOS on 40 meters thinks you're a crank) and Cell Phone users (whadda ya mean they don't have service in the middle of a wilderness area or during a massive power outage?). Nor is this limited to radio: flare guns (It's 2AM, a bear just ate your camp partner, and you're fifty miles from civilization in a valley. Shoot a flare off, and you've made your camp brighter for a few seconds and pissed off the bear. Feel better?) Air horns (same scenario, maybe the bear leaves if it's loud enough.) Resolving problems surrounding the first requirement simply means making sure there is a person listening. Perhaps someone you know, perhaps not. The 911 system, for example, consists of people continually monitoring a phone for incoming messages from senders. World-wide, satellites and many pilots listen to 121.5 Mhz on their radios, looking for distress signals. If a CB operator knew someone in the area who agreed to listen on channel 9 for 15 minutes at 6PM everyday, his chances of being heard then are vastly improved. The ham, who had punched in the frequency to his club's repeater, which has a long-tone-zero (LTZ) emergency alert system that gets friends from the club on would be in better shape too; and if the ham's friend was listening at 6PM everyday on 40 meters, it's doubtful his friend would think he was nuts if he said he needed help urgently. Having a friend look for a flare on a ridge line a hour before sunrise--and climbing to the ridge line to fire the flare--would work wonders, too. Note that in each of these cases, not only was someone listening, but there was coordination, also, in that the recipient of the messages knew when and where to look or listen. What have we learned? 1) Someone has to Send and someone needs to Listen. 2) Both have to use the same system. Both need to understand the message. 3) Coordination between the sender and listener vastly increases the likelihood of successful communications. A. Types of communications 1. Wired Communications a)Basic Telephone Service Current telephone communications, at least in industrialized nations, is the standard of excellence that most communications systems are compared. Disparaging comments and annoying customer service issues aside, standard phone service is nearly universal, approaches 100 percent reliability, and offers nearly instant connectivity to virtually any person in the industrialized world. Phone service is probably the single most utilized form of survival communications, used whenever 911 is dialed, or a person phones a friend for help. While basic phone has never been completely secure, it's become very apparent that phone services are approaching a nearly total security compromise, at least with respect to national agencies. Note that with modern signaling and billing records systems, every phone call is logged, and the phone number, which is effectively an address to a physical location for wired phones, is present with each call; this is true even of pay phones. The exposure risk associated with basic phone systems is extreme. Any communications which is intended to remain private probably shouldn't rely on phones. This is of no bearing for most conventional survival scenarios. Phone service can fail at any time, but due to very good survival engineering, basic phone service often stays operational days after AC power fails. Destruction of inside plant (central office switching equipment, batteries, and power generation) or outside plant (poles, wiring, and transmission equipment) will result in failure of service, of course. Note that in floods, hurricanes, and earthquakes phone service often fails in a widespread way, whereas failure in common storms and civil disorder is usually localized. Note that while phone service may continue to be reliable during a disaster, communications may be difficult due to overloading. During the summer of 1996, a power outage in the Western United States resulted in a flood of calls to 911 systems in several states from people simply reporting that their power was out; in some areas, 911 failed completely, or had hold times in excess of 30 minutes. a) Private Point-to-Point (Intercoms and Field Phones) Outside of PBXs located in buildings, private wired communications aren't very common. Two notable exceptions are intercom systems that are used to communicate within a building, and field phones, which are essentially military versions of intercoms. Intercoms are generally limited in range. So-called wireless intercoms use the AC power line to convey their signal, and are generally dependent on AC power themselves. Wired intercoms usually don t cover more than a few hundred feet in a building, due to the wiring difficulties. Such intercoms usually run on batteries. Field phones are generally used in environments where complete control of the lines of communication exist. The typical military field phone runs on two D cell batteries, and can operate over up to twenty miles of two-conductor wire. In general, private wired communications is the most secure, . The wires themselves can be followed if not concealed, revealing both points of communications. 1. Radio Signals There are a huge number of possible options for radio-based survival communications, ranging from getting broadcasts from authorities via a $4 AM radio to portable satellite phones. a) Broadcast Radio AM Radio Let s be blunt. If you can have only one radio, if you have less than ten bucks to buy equipment, forget CB, Ham, and everything else. Get a portable AM radio. The first radio band for survival, news, and government information is the old AM radio band, from 550 Khz to 1700 Khz. Equipment can be very small, with typical radios 1x3x4 in size, light, low-power (two AA batteries can run a radio for weeks at low volume or with earphones), cheap (Radio Shack's FlavorRadio is $7), very reliable (single IC), long range (100s of miles for clear-channel radio stations at night) In addition to the radios themselves being reliable, AM broadcast radio stations themselves are also fairly reliable with back-up transmitters, emergency generators, and bomb shelters: a few radio stations in every area are part of a extremely reliable network that is a carryover from the civil-defense radio network's heydays of the 1950's. The two civil defense frequencies are 640 Khz and 1240 Khz. As a result of the defense network carry-over, and the fact that many AM stations offer talk-radio call-in formats, AM radio is ideal for getting news and information during emergencies, probably more so than any other source. The military and other government agencies also maintain emergency portable radio stations for disaster-stuck areas, that are AM stations. Inexpensive AM radios with ferrite bar antennas have a secondary survival use as navigation instruments. Such radios have sharp, well-defined nulls where the signal goes dead. If one knows the direction of the nulls of the radio and the locations of the AM radio stations in the area, it's possible to triangulate your own location based on the directions your radio indicates each station is in. Accuracy isn't incredible, but it can generally give a position of +/- 5 miles if the radio stations are 50 miles away. Within the US, there was originally a set of stations set up with what is known as clear channels that made sure a single, high power station had no others within hundreds of miles on the same frequency. Currently these are known as Class A stations (which run 50,000 watts). These stations can be heard for hundreds of miles at night, allowing listeners in disaster-striken ares to hear stations that are in surviving areas. (for example: At night, one can hear WMAQ, Chicago on the eastern edge of the Colorado Rockies without much difficulty.) Refer to Appendix A for a list of Class A Clear Channel stations. a)Two-Way Radio 1)Unlicensed Services All radio services are regulated in some form, even if it's a law that states that the service is unregulated. However, there are several license-free services in the U.S. Note that other locations aren't quite as progressive in terms of unregulated services. The U.K., for example, requires CB radios to be licensed, and doesn't offer a free 1750 meter band. YMMV! CB Radio (AM and SSB) CB, also known as Citizen's Band (or Children's Band to its detractors) uses an amplitude-modulated signal on forty channels centered around 27 Mhz. These radios are limited by FCC regulation to four watts of output power going up the antenna. Typically, from a vehicle with an average antenna on flat terrain this results in a reliable range of ten to twenty miles. With a better antenna, considerably longer ranges are possible. However, another FCC regulation requires CB operators to take steps to prevent their signal from being detectable beyond 150 miles. CB frequencies are plagued with a number of problems, such as overcrowding on certain frequencies and considerable rudeness. Typically, Channel eleven is considered a general calling channel, and Channel nineteen is used by truckers. In addition, Channel nine is reserved by law for emergency use only. Refer to Appendix B for a list of Citizens Band Channel Frequency assignments. Part 15 Radio Bands So-called part 15 bands owe their name to the United State's Federal Communications Commission, which has a set of rules (Part 15) which allow certain types of unlicensed radio transmitters. There are three main part 15 bands that are commonly used for two-way voice communications (other bands exist under part 15 for a plethora of other devices.) The only band that's really significant is the 49 Mhz band; the other two are interesting, but probably impractical. 49 Mhz Radios The 49 Mhz band is a widely-used consumer radio band, primarily for cordless phones. There are 10 narrow-band FM channels between 49.67 and 50.00 Mhz assigned to the band (Refer to Appendix C). The band is relatively noise-free in non-industrial areas, though the millions of cordless phones means plenty of interference in highly urban settings. Power output is specified by field strength, 10,000 uVolts/meter at 3 meters, and translates to a few milliwatts. The band is most useful for short-range communications. The receivers of good radios are such that this low power gives a 1/4 mile range, though field tests show ranges of 1/8 to 1/2 mile, depending on terrain. The radios perform amazingly well in difficult, hilly terrain at short range. In very controlled tests using a lab-grade receiver/antenna, a detection range of three miles was obtained. Equipment is small and light, often only 1x3x7 or smaller; it's offered by many manufacturers that also make CB radio equipment. Power requirements are miniscule, with RX requirements of less then 20 milliwatts and TX requirements of 100 milliwatts. (In one test with a radio using three AA lithium batteries, run time in RX mode was two WEEKS continuous.) Though very reliable electrically, durability is a concern, as most equipment is built with light plastic cases and no waterproofing. Cost is generally $25-$40 per unit with features of single vs. multiple channel and voice-operated switching accounting for the cost difference. Note that kiddie walkie-talkies also operate on this band but the receivers of such radios are worthless. Due to the proliferation of small, inexpensive 2-way radios for this band, there is no realistic hope of private communications-indeed, it's entirely possible that this band will become so crowded as to be useless in the event of an emergency. In addition, there are no standard frequency uses or nets on this band. Considering the limited range, the primary use will likely be for tactical communications among a small group, such as coordinating camp activities. One group sends a scout ahead in difficult terrain while the rest of the backpacking party waits, with the scout calling back if the path taken is viable; this saves hours of useless backtracking. A secondary use is to place a radio with volume set on maximum on a pack that is cached in a well-camoflauged environment. The squelch keeps the radio quiet, but another radio can transmit sounds allowing the user to home-in on the hidden pack. The 49 Mhz band is smack-dab in the middle of the VHF-low band (30-88 Mhz, 25 Khz channel spacing) that the military use world-wide for primary tactical communications. It should be no surprise then that there's quite a variety of ground-based, airborne, and satellite-based radio equipment dedicated to intercepting, direction-finding, and jamming these frequencies, which include the 49 Mhz band. Theoretically, consumer 49 Mhz radios and military VHF-low radios should inter-operate. However, the reality is that only some military radios operate with narrow band FM, and the tuning steps of the radios are 25 Khz at best, frequently placing them off-channel. Newer tactical radios, such as the US Army SINCGARS (Single Channel Ground and Airborne Radio System, are usually operated in frequency-hopping mode, in which there is no hope of inter-operability (such radios can however be tuned to single channels) Although highly susceptible to interception and direction-finding, in practice the range of consumer radios on this band is so limited that this highly unlikely to occur unless a party is expressly searching for the signal in the immediate area; the short range also makes these one of the few radios immune to satellite-based DF. In urban environments there are literally hundreds of competing signals on the same frequency, making interception and DF difficult. Note that in scenarios involving military conflict, operational jammers could make these radios unusable at tens of miles away, and these radios are likely to be unintended victims, jammed simply because they're in the middle of a military band, and not due to overt intent. One group known to us has primary communications based on 49 Mhz radios. The limited range and extremely low power consumption were keys, along with the fact that the group stays close together 100% of the time were factors that lead to the decision. 460 Mhz Family Radio Service (FRS) The FRS radio service is a recent addition in the US and a good selection of low cost equipment is available. The radios are relatively low power 500-600 milliwatts (0.5-0.6 watts), and operate on 14 channels in the 460 Mhz frequency range using reliable FM modulation. The radios have a user settable squelch level control to minimize interference. In addition, the radios utilize a system known as Continuous Tone Coded Squelch System (CTCSS) which allows an additional degree of interference control. These radios have a useable range up to 2 miles depending on terrain conditions. Refer to Appendix D for a list of FRS frequencies and Appendix E for a discussion of CTCSS. 1750 Meter Lowfer Band In the US, the 1750-meter band allows radios to operate with 1 Watt of power into a 50 foot long transmission line/antenna system at frequencies in the 170 Khz (that s 0.170 Mhz) range with no license. This is a *really* low frequency. Equipment for 1750 meters is generally as small as one wants to build it. There are only a few commercially built radios for this band, generally the same size and weight as a larger mobile CB radio. Power consumption is quite low, with about 3 watts peak for TX and hundreds of milliwatts at most for RX. Cost is generally no more than $200 for a top-end commercial built radio. Antennas are inefficient and large, since the 50 foot limit really needs to be exploited for the radio to work well. Communication is therefore not very reliable at long ranges; however, at short ranges (a few miles) at night, when the noise level is low, 1750 meters is reliable. At night during the winter, it provides the greatest range, with reasonably reliable contacts at 100's of miles. During the summer this band is plagued with static making it rather unreliable. The 1750 Meter band is a (barely) plausible survival radio band only if it's used for a network among users that are located near each other. There are a few experimenters on this band that perform low-rate data communications using exotic modulation methods, but most prefer Morse code or SSB. There are no regularly monitored channels or survival networks in operation, though some radio enthusiasts in California do have a regular net. It is, however, worth noting, that some caving and spelunking enthusiasts also sometimes use this band, as low frequencies have some limited ability to penetrate obstacles such as the ground. (The same principle is used by the US Navy, which uses VLF and ELF signals to contact submarines) There's one survivalist of note that does use this band: the U.S. Government. A special high-survivability data network known as the ground-wave emergency network, or GWEN, can be heard between 150 and 170 Khz with a repetitive noise that sounds like a cross between a hiss and a crunching sound. This network is intended to survive a massive nuclear strike and provide low-data-rate post apocalyptic communications. Low frequencies are so easy to direction find that they are the basis of the first radio-navigation system used for aircraft and ships. Starting at about 200 Khz, there are thousands of low-power non-directional beacons (NDBs). Automatic-direction-finding (ADF) radios tuned to an NDB indicate their direction with high accuracy, and many ADF receivers are capable of tuning the 1750 meter band. On the plus side, although direction-finders work really well here, the low power and low frequency of the 1750 Meter band make it effective for covert communications; few receivers tune this low, and even fewer people even bother to listen. Due to the inefficiencies of the antenna system jamming is difficult, and there is no known deployed jamming equipment capable of disrupting this band. Micro-power AM and FM Also permitted under part 15 is low-power (100 milliwatts) AM transmitters with a 10 foot antenna restriction on the same band as broadcast AM radio. The AM band shares many characteristics and difficulties of the 1750-meter band. Equipment is generally always hand-made, usually from AM broadcast kits. Receivers can be cheap AM receivers, but a viable communication system will likely use a sensitive medium wave or short wave radio receiver. Cost of the transmitter can be as low as $20, the receiver $5 to $5000. Transmitter size is generally the size of a small mobile CB, about 2x6x6. Power consumption is minimal, under 1/2 watt. Reliable reception ranges of a 1/4 mile or so are common, though with good receivers and quiet band conditions (at night, during the winter time) on an unoccupied AM channel (rare in its own right) ranges of 100's of miles have been obtained. Signals are easy to direction find (indeed, many aircraft ADF systems also tune the AM radio band) and it s trivial to jam weak-signal reception in the AM band when Mother Nature isn't doing it herself with thunderstorms. No nets are known to use micro-power AM, though some pirate-radio broadcasts violate the FCC's power specification and some of these transmit vaguely survival-related gloom-and-doom conspiracy radio programming. This (with legal power, and probably better, community- related programming, of course) is probably the only viable use for this band in a survival context (weak as though that may be.) Micro-power FM stations are also permitted, but the large bandwidth and low power allowed makes micropower FM even more useless than AM. (1) Licensed/Regulated Services (a) Amateur ( Ham ) Radio The bands listed below all require a license for use in the United States and most other countries with one important exception: Under US law (Part 97 of the FCC regulations), a station may lawfully use any and all means at its disposal to locate help in the case of a legitimate emergency. 6-Meter Band The six-meter band (50-54 Mhz ham band) is considered sort of a "schizophrenic" band, that can't make up its mind whether to be a worldwide/distant contact band or a local VHF band. It generally has been known to be used as both of these. The use of this band is primarily a local phenomenon-extremely popular in some areas and completely silent in others. 2-Meter Band 2 Meters (144-148 Mhz.) is one of the most commonly used bands in the United States. Frequently these days, when a ham buys his first radio, it's a mobile or handheld 2-meter FM transceiver. SSB and CW are rarely, but occasionally used on this band. However, 2M is a favorite for amateur radio satellite and amateur Earth-Moon-Earth communications, and for technical reasons these methods require the use of SSB or CW rather than FM. This band, along with the 70-centimeter (432-450 Mhz) band, are among the most popular bands for local packet (data) radio communications, and are also hands-down favorites for Radio Amateur Civil Emergency Service (RACES) and Amateur Radio Emergency Service (ARES) communications. Licensure for the use of the above three bands in the United States is granted on the basis of two multiple-choice written examinations covering radio theory, amateur practice, and FCC regulations. The ARRL (website address above) maintains a list of examination sessions, and study guides for these exams are on the shelf in most libraries and bookstores. MF/HF Bam Bands: In the United States, ham radio bands exist at 1.8 Mhz, 3.5 Mhz, 7 Mhz, 10.1 Mhz, 14 Mhz, 21 Mhz, 24 Mhz, and 28 Mhz. These bands are all capable of long-distance communications, depending on atmospheric and sunspot conditions, and have all been used for worldwide communication. The most common emissions modes are CW (Morse Code) and Single Sideband, but certain data communications are also used. Equipment for these bands is all over the range in terms of price and complexity-low-power CW-only single frequency transmitters can be built for $20, and high end all-band all-mode transceivers can be bought for several thousand dollars. Literature on use of these bands is common, with "Low-Profile Amateur Radio" by Jim Kearman being an excellent (if basic) primer for people who want an introduction into low-power HF operation without much in the way of an antenna. A license from Federal Communications Commission is required to transmit on these bands (with limited exceptions explained above), and the license is based upon examination of the licensee's understanding of radio theory and law, and ability to receive and understand signals in the Morse code. (1)Commercial Carrier and Emergency Services Cellular Phones A Cellular phone is essentially a low-power UHF transceiver. When a call is made, the phone signals a fixed station called a 'cell.' The cell transfers the signals between the radio waves and the phone exchange. (A gross oversimplification, but detail is not required here). Cell phone conversations are not private, any more than any other radio conversation. Technically, the law says that they may not be monitored, but this law is unbelievably easy to violate. Scanners able to pick up cell frequencies are not sold to civilians any more, but they can be built. Cell phones also depend upon a working cell. A power outage for an extended period could result in shutdown. Also, cells can be overloaded. In the event of a disaster, a cell can handle a given number of calls. Calls that exceed the cell capacity will be rejected, rendering communications ineffective. Paging Paging is essentially a method of one-way radio communication. An individual makes a telephone call to a given phone number, and is prompted to enter a message. This message is then sent out over VHF or UHF radio to a specific pager. Some paging service allows the display of phone numbers. Others actually permit one to email a message to a pager. This service has an advantage, in that it can discreetly summon one to check in or go somewhere as needed, but is dependent upon a network of transmitter towers and phone lines, and therefore might not be fully functional in a disaster. In June of 1998 the complete failure of the Galaxy IV satellite caused a shutdown of 90% of the pagers in the continental US. This single point failure shows the fallacy of relying on a single comms system. a)Radio Operation and Procedures A radio-based communication system depend on two main elements to work: operational radio hardware, and procedures that allow the sender and receiver to communicate. 1)Radio Equipment, Antennas, and Propagation The dB or decibel (1/100th of a Bel) is a comparative measurement based on a log scale. That is, there's something measured against a reference. The decibel allows a very wide range of signal power to be represented with small, manageable numbers: Power Change Decibels 2X 3 dB 100X 20 dB 1,000,000X 60 dB 0.5 X -3 dB 0.000001X -60 dB Things that increase a signal are usually called gains and things that decrease a signal s strength are called losses, and both are usually measured in dB, with gains being positive and losses negative. Note that if we compare power to a fixed reference, such as a 1 Watt or one milliwatt, the dB can also be a measurement of actual power; a transmitter with a 20 dBW output, for example, has 100 Watts of power. There two major factors that determine total radio performance, known as station gain (what the equipment does) and path loss (what the environment does to the signal between the stations.) It may seem confusing, but it's as simple as this: If station gain is greater than path loss, you can communicate, otherwise, you can't. If you can't communicate, you need to fix one or more parts of the radio system until you have enough station gain. Use more power, a more sensitive/selective receiver, better or higher antennas. Typical station characteristics follow: Station Gain Factors Good Base SSB CB Transmit power +10 dBW (12 Watts) Transmitting antenna height gain +3 dB Transmitting antenna gain 0 dB Receiving antenna height gain +3 dB Receiving antenna gain 0 dB Receiver sensitivity +149 dB (-149 dBW) Total Station gain 165 dB The ultimate goal of the radio system is to get a signal to the receiver that's stronger than the background noise, so the signal can be heard. This is known as signal-to-noise ratio, and receiver sensitivity is usually stated as the lowest power level that will result in a given signal-to-noise ratio, typically 10 dB. Note that the receiver sensitivity is actually how much a signal can be reduced before it can t be heard (-149 dB) but it counts as a positive, as we have 149 dB in our station gain account that we can lose before we can't hear a signal anymore. The path loss is how of the signal is reduced by the environment. Distance, air, mountains, water vapor are some of these factors. Distance alone reduces the signal at a rate of the square of the distance, e.g., a signal two miles away is one-quarter the strength of a signal one mile away, just because of the distance. Path loss varies (just a little bit) with the frequency used until one gets to microwaves, where path loss jumps significantly. Under ordinary conditions between two stations on average terrain, path loss goes this way: Frequency 10 Miles 25 Miles 50 Miles 27 Mhz (CB) -135 dB -152 dB -174 dB 144 Mhz (2M ) -134 dB -157 dB -175 dB For a good SSB CB radio, we have 165 dB of station gain, and we can communicate as long as path losses are less than this; on average terrain, this is somewhere between 25 and 50 miles. Note that if the antennas used are poor and low to the ground, this will change things considerably, as we'll see in a few paragraphs. In situations where the signal is bouncing around, such as short wave radio signals, loss includes both distance and the efficiency that the signal is reflected; when conditions are good, this reflection efficiency can be 100%, and only the distance matters. Likewise, if a satellite is used, the path loss is pretty much a result of just the distances between the ground stations and the satellite involved. Distance-only path losses run about -110 dB for 100 miles, or a typical low-earth orbit, and -151 dB for 22,500 miles, or geo-syncronous orbits. No place on earth is more than 12,500 from any other location, so the path loss for a perfectly reflected short wave signal is somewhere in-between. Not that it's done, but our 165 dB of station gain is quite a bit more than the 151 dB path loss of a geo-synchronous satellite, so it's trivial for the satellite to hear a SSB CB or a 2-Meter Amateur radio. Indeed, several emergency systems depend on this: simple 1/2 watt emergency-radio beacons are detected with low-earth orbit satellites, and the newer 5-watt beacons are detected by geosyncronous weather satellites. In the late 1980's and early 1990's the space shuttle carried the SAREX (Satellite Amateur Radio Experiment) program. Astronaut hams utilizing the 2 meter (144-148 Mhz) band communicated to thousands of earth bound hams, many utilizing only low power (0.5-5 watt) hand held radios. (1)Basic Radio Antennas Antenna Effectiveness Antennas can be measured by listening to a standard transmitter on the frequency of interest, and changing the antenna and noting the changes in the signal. Higher-end radios have meters that show relative signal strength, using numbers of 1 to 9 (S1...S5...S9) and then dB over S9; each S-unit is typically 6 dB. Using a calibrated receiver, we did measurements of a local weather station (near the amateur 2-meter band) to illustrate several antennas. We used the best antenna (which isn't very good at all, actually) as a reference, and then compared several portable antennas: Antenna Sig. Strength dB % Signal Discone at 20 feet S9 0 dB 100% 1/2 Wave Rod 6 S5 -24 dB 40% Rubber duck, 6 S3 -36 dB 2.5% Doing the same thing at CB frequencies: Antenna Sig. Strength dB % Signal Dipole at 20 feet S9 0 dB 100% Rubber duck, 6 S0 -54 dB .0004% Poor antennas will reduce station gain; indeed is we use the SSB CB example where we had 165 dB of station gain, and change the antennas used to rubber duck antennas, the station gain plunges to just 51 dB, not even enough to cover five miles! What these measurements show is that antennas can compromise perfectly good equipment, and that it takes a good antenna for a radio to work well. There are several types of antennas that are easily built with wire or stiff metal rods that are suitable for survival use and are also good antennas. As a general rule, if you want maximum range and station gain, use a good antenna and place it as high as possible, including climbing up mountains or hills. (a) 1/4 WaveLength Vertical This is perhaps the simplest antenna. Basically, it's a vertical rod or stiff wire fed by a feed line at the bottom and cut to about one quarter of the desired wavelength. It radiates uniformly in all directions, and is the most common type for handheld and vehicle-mounted radios. (b)Dipole Another simple antenna. Basically, it consists of two wire "legs" of 1/4 wavelength each pointed in opposite directions, and either horizontal or sloped. This antenna is most commonly used for Medium and High-Frequency ham radio and short wave listening (1.8-30 Mhz). It radiates most strongly in a direction perpendicular to the long axis of the wires. The overall length in feet is calculated by the simple equation: 468/Freq (in Mhz). For example a dipole cut to operate on 3950 Khz (3.95 Mhz) would be 468/3.95 or 118.5 feet total length of 59.25 (60 feet) on each leg. This length if generally only critical for transmitting. Quads and Yagis Quads and Yagis are two types of directional antennas. A Yagi has a center element, called a driven element, which is connected to the feed line from the transmitter. This element is cut to roughly one- quarter of the desired wavelength, and mounted on a horizontal boom. Then, slightly shorter elements, called "director elements" are cut and mounted on the boom on one side of the driven element. Slightly longer elements, called "reflector elements" are cut and mounted on the other side, and the whole antenna is generally mounted on a rotatable mount. The director and reflector elements are typically each 5% shorter of longer than the previous one of the same type. These types of antennae tend to be highly directional, favoring the direction towards the director elements, and are frequently used for HF, VHF, and UHF ham radio stations. (1)Signal Operating Instructions and Radio Nets Signal Operating Instructions (SOI) is the military name given to a whole host of methods and procedures to communicate; essentially, SOI is a protocol of behavior for people and equipment to communicate successfully. The single most important thing to remember is that that it takes someone listening for communications to work, and the best radios in the world are useless if no one hears you call for help. Establishing or connecting to a radio net of listeners, making sure that someone is out there listening for you, is the single most important step to take in radio communications. Period. Schedules It's impractical for most people to listen to radios continuously, so having a schedule for stations on your net to listen makes radio communication practical. Either use a published schedule, or a regular interval (every day at 7pm, for example) for the net to come on-line. Guard Channels All radio users need to be on the same frequency to communicate. A special listening frequency makes monitoring easy; for example, on CB radios, channel 9 is used only for emergency traffic, so you can listen to this channel and know if you hear something, it is (at least in theory) important. In many areas, there are amateur radio repeaters with a feature known as LTZ (Long-tone-zero) which is used to turn on receivers of regular listeners, for when help is needed. Your radio net should have a guard channel to listen to when the net isn't active, and a one or more net channels for when it is. (Depending on other factors, these channels may be changed regularly or not.) Codes In general, the use of codes, ciphers, and other encryption on most radios is illegal in the United States if the intent of the code is to obscure the meaning of a message. There are legal uses for codes in CB and ham radios-see below under "Brevity and Message Coding" Authentication Authentication is the art of verifying that all people in a given net are people who have legitimate access, for example through the use of unannounced questions. For example, during World War Two, it was a popular perception that no German soldier would know anything about baseball. As a result, American GI's would frequently quiz each other about baseball trivia to be sure that everyone present was in fact an American. (There have been horror stories about American generals who knew nothing about Shoeless Joe Jackson and spent more time under guard than they would have liked, which goes to prove that an authentication system should not be so haphazardly managed on a large scale) Brevity and Message Coding Radio communication takes time and bandwidth. Certain codes have become agreed-upon conventions to compress a relatively large amount of information into a relatively small amount of space. For example, almost everyone who listens to a CB or to police radio has heard the "Ten codes" in which a sender may say "Ten-four" and be understood by everyone listening as having said "Your message is acknowledged" Refer to Appendix H: Amateur Radio Q-Signals for an additional standard list of specialized abbreviations. SOI Spares Having extra copies of your Signal Operating Instructions can be a double-edged sword. On one hand, if your SOI is at all complex or elaborate, losing your only copy could be crippling. However, if your net's integrity depends upon not having your procedures widely known, an extra SOI is a copy of the SOI waiting to fall into the wrong hands. Alternately, multiple copies of SOI's with attached authentication codes may also be utilized. 1. Visual Signals Morse code by light Ships carry a set of blinker lights for communication by morse code. These lights are essentially searchlights fitted with shrouds or shutters that can be quickly opened or closed. Semaphore In the days before wired telegraphy, a code was used to send messages over long distances called semaphore. Basically, the sender stood atop a hill holding a brightly colored flag in each hand. He would face the receiving station and raise his arms up out to his sides, and the angle at which he held his arms would signify a given numeral or letter. Three-in-a-row rule (whistles, gunshots...) In general, three of any signal repeated at a regular interval signifies distress. For example, a hunter who is lost can fire three shots in the air a few seconds apart. Theoretically, anybody in the vicinity will hear the three shots and realize that the hunter is in some sort of distress, and will be able to figure out the direction to search from the sound of the shots. As a practical matter, it's unlikely that such a signal will be taken seriously unless the sender waits until after dark. After dark during hunting season at least the local game officer will be hunting you. American sign language Sign language consists of an alphabet and a set of symbols each represented by a set of hand signals. This information is quiet, covert, and generally unknown within the non-hearing impaired community. Like Morse and Semaphore is could provide a clandestine and useful communications alternative with practice. GLOSSARY AM: Amplitude Modulation CTCSS Continuous Tone Coded Squelch System (CTCSS) Refer to Appendix E CW: Continuous Wave DTMF: Dual Tone Multi-Frequency Refer to Appendix G FM: Frequency Modulation LTZ: Long Tone Zero - Transmission of a DTMF '0' for a long relative time (usually > 2-3 seconds) used for specific control of repeaters and related equipment. LSB: Lower Side Band Modulation: The mechanism for impressing information (voice or data) onto a carrier frequency. NET: Network SSB: Single Side Band USB: Upper Side Band Sub-Audible: Refer to CTCSS Appendix A: AM Class A Clear Channel Stations FREQ CALL CITY STATE 640 KYUK BETHEL AK 650 KYAK ANCHORAGE AK 660 KFAR FAIRBANKS AK 670 KDLG DILLINGHAM AK 680 KBRW BARROW AK 700 KBYR ANCHORAGE AK 720 KOTZ KOTZEBUE AK 750 KFQD ANCHORAGE AK 770 KCHU VALDEZ AK 780 KNOM NOME AK 820 KCBF FAIRBANKS AK 840 KABN LONG ISLAND AK 850 KICY NOME AK 890 KBBI HOMER AK 1020 KFFR EAGLE RIVER AK 1080 KASH ANCHORAGE AK 1170 KJNP NORTH POLE AK 1090 KAAY LITTLE ROCK AR 580 CMJP CIEGO DE AVILA, CAM. CA 640 KFI LOS ANGELES CA 680 KNBR SAN FRANCISCO CA 810 KGO SAN FRANCISCO CA 900 CMJV CIEGO DE AVILA CA 1070 KNX LOS ANGELES CA 850 KOA DENVER CO 1080 WTIC HARTFORD CT 750 WSB ATLANTA GA 1040 WHO DES MOINES IA 670 WMAQ CHICAGO IL 720 WGN CHICAGO IL 780 WBBM CHICAGO IL 890 WLS CHICAGO IL 1000 WMVP CHICAGO IL 1190 WOWO FORT WAYNE IN 840 WHAS LOUISVILLE KY 870 WWL NEW ORLEANS LA 1130 KWKH SHREVEPORT LA 1030 WBZ BOSTON MA 1090 WBAL BALTIMORE MD 760 WJR DETROIT MI 830 WCCO MINNEAPOLIS MN 1120 KMOX ST. LOUIS MO 1110 WBT CHARLOTTE NC 1110 KFAB OMAHA NE 660 WFAN NEW YORK NY 710 WOR NEW YORK NY 770 WABC NEW YORK NY 810 WGY SCHENECTADY NY 880 WCBS NEW YORK NY 1130 WBBR NEW YORK NY 1180 WHAM ROCHESTER NY 700 WLW CINCINNATI OH 1100 WTAM CLEVELAND OH 1170 KVOO TULSA OK 1190 KEX PORTLAND OR 1020 KDKA PITTSBURGH PA 1060 KYW PHILADELPHIA PA 1210 WPHT PHILADELPHIA PA 550 CMAA PINAR DEL RIO PR 740 CMAC PINAR DEL RIO PR 740 CMAB PINAR DEL RIO PR 650 WSM NASHVILLE TN 820 WBAP FORT WORTH TX 1080 KRLD DALLAS TX 1200 WOAI SAN ANTONIO TX 1160 KSL SALT LAKE CITY UT 1140 WRVA RICHMOND VA 710 KIRO SEATTLE WA 1000 KOMO SEATTLE WA 1170 WWVA WHEELING WV (As a personal note from the editor, WBBM-780 Chicago deserves special credit for being a solid general news outlet in normal times) Appendix B: Citizens Band Channel Frequencies Channel Freq Channel Freq Channel Freq Channel Freq Number Mhz Number Mhz Number Mhz Number Mhz 1 26.965 11 27.000 21 27.215 31 27.315 2 26.975 12 27.105 22 27.225 32 27.325 3 26.985 13 27.115 23 27.255 33 27.335 4 27.005 14 27.125 24 27.235 34 27.345 5 27.015 15 27.135 25 27.245 35 27.355 6 27.025 16 27.155 26 27.265 36 27.365 7 27.035 17 27.165 27 27.275 37 27.375 8 27.055 18 27.175 28 27.285 38 27.385 9 27.065 19 27.185 29 27.295 39 27.395 10 27.075 20 27.205 30 27.215 40 27.405 Appendix C: 49 Mhz Channel Frequencies Base Handset 46.61 49.67 Cordless phone Ch 1 46.63 49.845 Cordless phone Ch 2 46.67 49.86 Cordless phone Ch 3 46.71 49.77 Cordless phone Ch 4 46.73 49.875 Cordless phone Ch 5 46.77 49.83 Cordless phone Ch 6 46.83 49.89 Cordless phone Ch 7 46.87 49.93 Cordless phone Ch 8 46.93 49.99 Cordless phone Ch 9 46.97 49.97 Cordless phone Ch 10 Appendix D: 460 Mhz Family Radio Service (FRS) Channel Frequencies 01: 462.5625 08: 467.5625 Modulation is FM 02: 462.5875 09: 467.5875 03: 462.6125 10: 467.6125 04: 462.6375 11: 467.6375 05: 462.6625 12: 467.6625 06: 462.6875 13: 467.6875 07: 462.7125 14: 467.7125 CTCSS (Coded Tone Carrier Squelch System) The CTCSS System prevents unwanted noise and/or conversation from being heard through your FRS radio's speaker. Only signals with the correct code will be heard. To use the system each radio must: A) be on the same channel B) have the same CTCSS Code selected. When enabled, the Privacy Code is transmitted with each voice message. All receivers programmed with the same code will open their speaker circuits and the message will be heard. It is VERY important to note that conversations on your FRS radio are NOT private. Any other FRS radio or scanner can eaves drop on your conversation. Also, it is always best to monitor, with the monitor button, prior to transmitting to prevent disrupting any nearby conversations that you may not hear on the channel. Appendix E: Continuous Tone Coded Squelch System (CTCSS) Sub-audble audio frequencies in Hertz 01: 67.0 09: 91.5 17: 118.8 25: 156.7 33: 210.7 02: 71.9 10: 94.8 18: 123.0 26: 162.2 34: 218.1 03: 74.4 11: 97.4 19: 127.3 27: 167.9 35: 225.7 04: 77.0 12: 100.0 20: 131.8 28: 173.8 36: 233.6 05: 79.7 13: 103.5 21: 136.5 29: 179.9 37: 241.8 06: 82.5 14: 107.2 22: 141.3 30: 186.2 38: 250.3 07: 85.4 15: 110.9 23: 146.2 31: 192.8 08: 88.5 16: 114.8 24: 151.4 32: 203.5 Appendix F: Emergency Frequencies HF Marine emergency frequencys. 2182, 4125, 6215, 8291, 12290, 16420 voice communications (SSB) Aviation 121.5 Mhz Voice or beacon Military 223.0 Mhz Voice or beacon EPIRB 121.5, 223.0, 406mhz 406 beacon is digital only with beacon on 121.5 and 223.0 CB channel 9, 27.065 VHF marine freq Channel 16, 156.800mhz GMRS 462.675 unoffical emergency/traffic/travel aid request freq. FCC estimates that %30 of the US is monitored by an official group REACT on this freq. Non-emergency but usefull frequencies: NOAA weather 162.40, 162.475, 162.55, 162.525, 162.5 Ham calling freq 6 meters 52.525 2 meters 146.52 1 3/4 meter 223.5 70cm 446.0 1296 1294.5 Appendix G: Dual Tone Multi-Frequency (DTMF) Audio Frequencies These are the tones transmitted when you press a key on your telephone touch pad. The tone of the button is the sum of the column and row tones. The ABCD keys do not exist on standard telephones. 1209 1336 1477 1633 697 1 2 3 A 770 4 5 6 B 852 7 8 9 C 941 * 0 # D Appendix H: IARU Phonetic Alphabet In a noisy environment, phonetic spelling of certain words made be required for understanding. This is the standard phonetic alphabet utilized by military and aviation as specified by the International Administrative Radio Union, which is a international governing body on communications standards. Example: IARU - Say: "IARU I Spell, India, Alpha, Romeo, Uniform" A: Alpha N: November B: Bravo O: Oscar C: Charlie P: Papa D: Delta Q: Quebec E: Echo R: Romeo F: Foxtrot S: Sierra G: Golf T: Tango H: Hotel U: Uniform I: India V: Victor J: Juliet W: Wiskey K: Kilo X: X-Ray L: Lima Y: Yankee M: Mike Z: Zulu Appendix I: Amateur Radio Q-Signals These signals are a form of legal code, used to shorten Morse Code messages by compressing a complete idea into three letters. Following the Q signal with an question mark makes it interrogative QRG: Will you tell me my exact frequency?/Your exact frequency is _____ QRL: Are you busy?/I am busy. Please do not interfere. QRM: Is my transmission being interfered with?/Your transmission is being interfered with ___ (1= nil; 2=slighly; 3= moderately; 4= severely; 5= extremely) QRN: Are you troubled by static?/I am troubled by static ___(1-5 as under QRM) QRO: Shall I increase power?Please increase power. QRP: Shall I decrease power?/Please decrease power. QRQ: Shall I send faster?/Please send faster. QRS: Shall I send slower?/Please send slower. QRT: Shall I stop sending?/Please stop sending. QRU: Have you anything for me?/I have nothing for you. QRV: Are you ready?/I am ready. QRX: When will you call me again?/I will call you again at ____ hours. QRZ: Who is calling me?/You are being called by ____ QSB: Are my signals fading?/Your signals are fading. QSK: Can you hear me betwen your signals and if so can I break in on your transmission?/I can hear you between my signals; break in on my transmission. QSL: Can you acknowledge receipt of a signal?/ I acknowledge receipt. QSN: Did you hear me on (____) kHz?/I heard you on (____) kHz. QSO: Can you communicate with ____directly or through relay?/I can commicate with ____directly or through relay. QSP: WIll you relay to ____?/I will relay to ____. QST: General call preceding a message to all stations. QSX: Will you listen to ____ on ____ kHz?/I will listen to ____ on ____ kHz. QSY: Shall I change to transmission on another frequency?/Change to transmission on ____ kHz. QTB: Do you agree with my counting of words?/I do not agree with your counting of words. I will repeat the first letter of each word or group. QTC: How many messages have you to send?/I have ____ messages for you. QTH: What is your location?/My location is____ QTR: What is the correct time?/The correct time is ____ (Timezone stamp)