This article replaces the old "CB Radio Primer for 4x4s", written in 1998. If all you want is CB radio information, you can skip this article and read the CB Primer instead.

The purpose of this article is to present and discuss the various options for communicating in the back-country. I understand that most four-wheelers aren't concerned with the hows and whys, and are merely looking for ideas and recommendations, so I've attempted to create an in-depth article while keeping it relatively non-technical. When I first started writing it, my intention was to make it a quick, basic guide. After a couple days of revisions, it evolved into more of a crash course containing practically everything I could talk about relating to 4x4 communications. I've realized that sections of it start to sound fairly technical, but I think that most people can understand what I'm trying to say.

I have worked in the radio-communications industry in the past, both in managing the two-way radio division of a communications company, and in selling and installing commercial two-way radio equipment. As a hobbiest, I am an Advanced-class amateur radio operator, and I've been refining the communications systems in my own 4x4's since 1987. I don't pretend to know everything, and some people may disagree with some of my ideas and opinions, but this is based on my own experience.

Written by Greg Sue
http://4wd.media-north.com/
Copyright © 2003. All rights reserved.
This article may not be reproduced, in whole or in part, without the express written permission of the author.

Introduction

Why do we need communications?

Issues specific to 4x4's

Methods of communications

Two-way radio

Mobile telephone

Two-way radio

Citizen's Band (CB)

Family Radio Service (FRS)

Commercial VHF (aka Business Band)

High Frequency (HF, aka Short Wave)

Amateur Radio (Ham)

Mobile telephone

Cellular

Autotel

Mobiltel

Satellite

Antennas

Physical characteristics

Gain

Mount type

Mounting location

Two-way radio, Autotel, and Mobiltel

Cellular

Antenna matching

Coaxial cable

Installation

General considerations

Power source

Permanent mounting

Temporary mounting

Accessories

Related equipment

Global Positioning System (GPS)

Scanners

Communicating effectively

Phonetic alphabet

Introduction


"Communications" is the sending or receiving of information. We do it all the time in our day-to-day lives, whether we're talking to somebody in person, calling somebody on the telephone, or waving at somebody on the street.

In our 4x4's, we can have the ability to communicate with the other vehicles in our group, or with the outside world, if we're carrying the appropriate communications equipment. We are usually out in the wilderness, far away from such amenities as pay phones and ambulance stations. We must rely on ourselves, and the people who are with us. Being able to effectively communicate with these people provides us with a good measure of safety and convenience on the trail.

If you're reading this article, you've probably already experienced the result of poor communications gear on the trail; failed equipment, short range, unintelligibility at close range, and no telephone service from your hand-held cellular phone. Many people "beef up" components to increase the reliability, driveability, and capability of their trucks on the trail, but install the cheapest CB radio and antenna they can find. I treat my communications gear like I treat the other components of my 4x4; I use the best gear that I can afford, and make sure that it's installed properly. Just like anything else on your 4x4, if you need it, it needs to work.

Why do we need communications?

When travelling the backroads, we frequently find it necessary to

notify other vehicles about road hazards or changes in direction

keep in touch when spread out over several kilometres

request information

coordinate winching exercises

call for help

My 4x4 group also uses our radios when we encounter multiple trails and don't know which direction to go; we can send trucks off in different directions to check out the roads, and can relay the information back to the others. This saves time as it doesn't require everyone to check out each individual trail, or have to wait for the trucks to return to report their findings.

If you're racing, keeping in touch with your chase truck or your spotter should be an essential part of your race strategy, and with the added danger that a competition offers, being able to request immediate emergency assistance is vital, not only for yourself, but also for a fellow competitor who may have crashed and is suffering from life-threatening injuries.

Issues specific to 4x4's

The nature of our hobby requires us to have equipment that is up to the task, and equipment that will work when needed. Physical considerations include aspects such as vibration, temperature, dust, and moisture. Environmental considerations include operating range (distance), surrounding terrain, and availability of services (mobile phone coverage, radio repeaters, etc.).

The constant pounding and jarring caused by the terrain we traverse means that our permanently-mounted communications gear must be solidly mounted. Use quality fasteners throughout; replace unknown screws and bolts with graded or stainless components. Nuts should be accompanied by lock washers, or you can replace them with Nylocs. Mounting brackets should be anchored to metal, not to plastic. If the factory mounting bracket is unsuitable for the intended location, you can fabricate a stout mounting system from aluminum or steel. While steel is generally stronger and can be made thinner, aluminum is easy to work with, and is the material that I prefer. Finally, you should not rely on "crimp" connections for your wiring; they will work loose and will cause frustrating intermittent problems. All connections should be soldered, and covered with heat-shrink tubing. That is not to say that you should not use crimp-type connectors in your wiring; I use the ring-type connectors for power and ground connections, but I solder as well as crimp them. Please read the article on how to properly install crimp connectors. This does not apply to coax connectors; NEVER use crimp-type connectors on your antenna cable. Good-quality communications gear will have Mil-Spec ratings; a Mil-Std rating of C, D, and E, for vibration, shock, etc. is desirable. I'm not aware of any CB's that have this rating.

Extreme temperatures are also an issue, as we can be travelling through a scorching desert in the middle of summer, or we could be stuck in a high-altitude ice storm in the dead of winter. I had an LCD display freeze up on one of my radios during a winter expedition; as a result I had no idea what frequency I was on.

I've found dust to be a major killer of radios. Although the problem can sometimes be easily fixed by an application of compressed air, consumer-grade radios tend to die quickly, and I've had several CB's fail because of this. As a result, I no longer have a CB in my truck, because I can't rely on it.

Moisture is another unavoidable aspect of four-wheeling. If your 4x4 of choice is an open-top vehicle, consider mounting the radio into the dash with a marine anti-splash cover that flips up to allow access to the radio controls, and even an upgrade to marine speakers for your stereo. If you're like me, mount your radio up high so that when the water comes pouring in through your so-called door seals, you'll still be able to holler for help. Some radios are inherently better at fending off water, and some can be helped with the application of silicone sealant along the case edges. Microphones and speakers can be made splash-resistant by sandwiching a piece of your wife's nylon stocking between the front of the microphone element or speaker, and the case grille.

Physical terrain is another consideration. If you are travelling in a wide-open desert and require long-range communications, a high-gain antenna, which is physically long, is desirable. If your primary terrain includes overgrown trails with low-hanging branches, a physically shorter (and thus lower gain) antenna should be used, along with a shock spring.

The type of communications gear we select is dependent on whom we need to contact. Simple nearby truck-to-truck communications can be done via CB or FRS; longer ranges require better equipment. Telephone communications is unreliable at best; while most cities, towns, and major highways have some sort of mobile telephone coverage, many of the areas that we travel in do not. The exception is satellite phone, which is fine if you can afford it or if your company has provided one to you, but the cost is generally beyond the financial grasp of us mere mortals. Cellular service exists at most major urban areas and along much of BC's highways, but even your selection of cellular provider can determine whether you can make a call or not.

Methods of communications

Two-way radio

Two-way radio is the most-common method of trail communications. It includes CB, FRS, VHF, HF, Ham, and others not covered in the article. By far, CB's are the most common two-way radios found in 4x4's, although locally, FRS radios are catching on fast because of their low cost, portability, ease of installation (none!), and better audio quality than CB's (for some models in certain situations, anyways; more on this later). Generally, CB and FRS radios are considered "short distance" radios; their reliable range is typically limited to around two or three kilometers, depending on the surrounding terrain and other factors.

Two-way radio offers "instantaneous" communications anywhere; ie. you push a button and you're talking. No dialing delays, and you don't have to be within a certain "coverage area" like you do with a mobile telephone. However, you can only communicate with those who have similar equipment.

Mobile telephone

The ability to make phone calls from practically anywhere is a great convenience and an excellent safety measure. Most people are aware of and own hand-held cellular phones, but only certain cellular providers (companies) cover the remote areas we frequent. Satellite phones can be used practically anywhere, as long as the antenna can "see" the communications satellite. However, the cost of these units and their actual usage is still fairly expensive.

Obviously, you must be within your mobile telephone provider's "coverage area" in order to use the service. The advantage is that you can talk to the outside world, not just the nearby trucks.

Two-way radio


While there are other types of two-way radio communications not covered in this article, I am concentrating on the most popular options. I'd also like to mention that it is not legal to use Marine or Avionic radios for land-based communications.

Special note regarding Mike radios: Although the Mike phone service (known as Nextel in America) offers a two-way communications mode, it will only work where there is Mike phone coverage, and there is a per-minute fee for usage. Due to the limited availability of Mike coverage outside of metropolitan areas, I cannot consider Mike's two-way service suitable for our purposes. This also applies to "trunked" radio systems.

Citizen's Band (CB)

CB is the most popular form of two-way radio communications found in 4x4's, with most four-wheelers in my area monitoring Ch-4. I've also found it to be the most unreliable method of communications for several reasons, the most common being installation-related. Many people who have installed a CB radio into their truck have no idea what they're doing, resulting in a poor installation and poor communications. Also, many people will buy the cheapest piece of crap radio and antenna they can find, and wonder why they can't communicate with their buddies much past a kilometre.

In Canada, CB radios utilize 40 frequencies between 26.965 MHz and 27.405 Mhz, in the 11-metre HF band. The primary operating mode is AM (amplitude modulation), and high-end radios also have SSB (single-sideband). They are intended for medium-range communications, maximum 30 miles, but in reality, the effective truck-to-truck range is considerably less. However, due to the nature of the HF bands, radio signals can travel up to the ionosphere, and be reflected back down to earth hundreds or thousands of miles away. This phenomenon is known as "skip", and is why you can sometimes hear overpowered base stations from southern United States calling "Aaaaaudio!" all day long.

New mobile units can be purchased for as little as $50 or less, and fancier radios can exceed $500. Hand-held CB's are also available; they are useful for short distances only, and usually lack some of the desirable features of their higher-powered brothers, but they are useful for spotting or winching exercises. You can expect to pay between $150-$250 for a decent mobile CB (all prices are $Cdn). When shopping for a CB, these two features should be present:

RF Gain - allows you to adjust the sensitivity of your receiver. This is useful when the vehicles you are communicating with are in very close proximity; turning the sensitivity down will eliminate the distortion that occurs when their radios overload your receiver. If you don't have an RF Gain control, nearby radios will sound muffled.

NB or ANL - noise blanker or automatic noise limiter. Helps to reduce ignition and atmospheric noise, and is usually left in the "on" position.

CBs which do not include these two features are not really suitable for our purposes. Yes, I know that your friend has a cheapie radio in his truck without these features, and it "works just fine". However, that may be a result of other factors, such as a cleaner electrical system, antenna choice and placement, or the better radios in your group "compensating" for his radio.

The radios that I personally like the best are made by Uniden, which include Uniden, Cobra, President, some Realistic (RadioShack), and numerous other off-brands. The decent models have excellent filtering and a nice audio section. Current models that I recommend are the Cobra 148GTL (aka President Grant) AM/SSB mobile, and the Cobra 29LTD Classic AM-only mobile.

Some models have "VHF weather radio receive"; however, the sensitivity of a CB on VHF frequencies with a CB antenna is not all that great, so I don't recommend paying extra for this feature if you have a choice. Some newer Cobra radios have a feature called "SoundTracker"; this is only useful if every radio in your group has it, so once again, I don't recommend paying extra for a radio just to get this feature. Also, while a fancy "SSB" radio is nice, most 'wheelers have AM-only radios; if the main purpose of purchasing a CB is to talk to them, then save your money and buy an AM-only radio. If everyone in your group has SSB, then you can switch over and enjoy the increased range and quieter operation that SSB offers.

There are many small-sized CBs on the market; while they fit nicely into tight spaces, they generally have less filtering (against ignition noise, atmospheric noise, and adjacent channel interference) than the larger units. As well, these smaller radios rarely put out the full legal 4-watt RF output power, and are usually set somewhere between 3 watts and 3.5 watts. Finally, most smaller radios use a smaller speaker due to the case size, making the received audio sound a bit tinny; this can be improved with the use of an external speaker.

Some CBs use LCDs (liquid crystal displays) instead of LEDs (light emitting diodes) to display the channel number; I prefer LEDs to LCDs as I have had LCDs freeze up in cold weather. Those of you in warmer climates may not have to worry about this.

A good deal can sometimes be found on used radios, although the usual caveats apply. Models to watch for include the Cobra 138XLR, President Grant (old board) and Thomas J., Realistic TRC-449, TRC-450, TRC-451, Cobra 146GTL, and pretty much any 28-series and 29-series Cobra radio. Beware of buying a used radio from an unqualified individual who thinks he's a CB technician; these radios are frequently "screwdrivered" in an attempt to garner increased power, which frequently results in detuning the radio and can result in your transmissions causing interference to other services via "harmonics" (numeric multiples of your transmitted frequency), such as public safety and television.

In some countries, "export CB's" are available; these have added features such as as FM (frequency modulation), more channels, higher power, etc. Many of these radios are marketed as 10-meter ham radios, easily modified for CB. Some models include Cobra 148GTL-DX, RCI-2950, President Lincoln, President Jackson, Uniden HR-2510, and others sold under the "Galaxy" and "Superstar" brand names. Almost all of these radios are manufactured by Uniden, and are the same size as the Cobra 148GTL. In Canada, it's illegal to use these radios on CB frequencies.

Speaking of illegal, don't bother with a "linear amplifier". These amplifiers are designed to increase your transmit range by boosting your RF power output. The problem with that is for close-in use on the trail, you will sound muffled to everyone within several kilometres, so it's useless for our purposes. In addition, cheap "CB" amplifiers do not incorporate filtering, and greatly increase the potential for harmonic interference.

In Canada, CBs are license-exempt.

Note: In Australia, there are two types of CB radios. They have the same 27 MHz units that we have, and they also have a 40-ch UHF CB service that operates in the 476-477 MHz range. The UHF CB's are very popular with local emergency organizations, and some have repeaters set up for increased range. As usual, the 27MHz CBs use AM (Amplitude Modulation), and the UHF radios use FM (frequency modulation), which basically means that the UHF CBs are much clearer than the 27 MHz CBs.

Family Radio Service (FRS)

FRS radios operate on 14 frequencies in the 462-468 MHz portion of the UHF band. They are intended for line-of-sight short-range communications, and have an RF power output of 500mW. However, FRS radios use FM (frequency modulation), and as a result the transmissions are generally clearer than those found on CB. When located at a high altitude such as a mountain ledge, it's not unusual to hear conversations from a nearby city or town several kilometres away.

I've tested units from Audiovox, Cobra, GE, Motorola, and others, and have found that Motorola makes the best units. Both the transmitted and received audio are clear, while other makes sound muffled and even unintelligible. Basically, don't waste your money on anything but a Motorola FRS radio.

Most radios have "38 privacy codes", which basically allows you to transmit a sub-audible tone along with your voice. If all radios in your group have the same tone set up, your users will only hear transmissions from radios equipped with that tone, which usually means you won't hear any other transmissions except those originating from your group, which is very useful in an area with lots of radio users. The only disadvantage to having this feature enabled is that you won't hear users from outside your group calling for help, so you may want to disable this feature when you're outside of the city.

Other features are available which include signalling, call tones, and voice privacy (scrambling); generally they aren't needed, and I'm not going to bother discussing them here.

Motorola FRS radios are available very inexpensively on Ebay; I've seen daily listings for refurbished high-end Motorola units for US$9.99 each, and brand-new high-end Motorola units for around US$40-70 per pair. Motorola even sells directly on Ebay; look for the "Direct from Motorola" logo in the listings.

Most Motorola FRS radios operate on 3xAA 1.5v batteries; you can buy a pair of nickle-cadmium rechargeable packs and a two-unit charger for around US$20.00 new on Ebay. If you are planning on using your radios in a cold-weather environment, I suggest using alkalines or lithium-ion rechargeables, as nickle-cadmium batteries tend to fail in cold temperatures. Also, it wouldn't hurt to have a spare set of alkalines on hand, in the event that you're out late and cannot recharge your rechargeable batteries.

Garmin has come out with FRS radios with GPS built in; their "Rino" units have the ability to send their GPS coordinates over the airwaves to other Rino radios. I have not tested these units and cannot say how well the FRS portion performs.

In Canada, FRS radios are license-exempt.

Note: Americans also have access to the General Mobile Radio Service (GMRS); these radios operate on frequencies similar to FRS, but the radios are higher power and require licensing from the federal government. Although some frequencies are identical and communications between the two services is physically possible, cross-service communications is illegal.

Commercial VHF (aka Business Band)

Many serious users utilize VHF radios; these radios are similar to (if not the same as) those used by emergency agencies such as police and fire departments, and commercial users such as taxis and logging trucks. VHF, while considered "line of site" communications, has excellent medium-range coverage; our 4x4 group typically gets a maximum range of 10 to 100 km's between vehicles, depending on a number of factors such as surrounding terrain, height, and antenna type. New units typically sell for between $500-$1500, depending on features, and used units can be had for as little as $150 for a "basic" unit.

For our purposes, commercial VHF is by far the best means of radio communications. The radios are built to a higher standard than CB radios, ham radios, and FRS radios. The radios have limited user controls, which makes them easy to use when you're crawling a twisty trail through the trees, or speeding across the Baja in the dark. VHF is supposed to be line-of-sight communications, but the radio waves will reflect off buildings, mountains, and other terrain, so you can still talk to other stations even though you may not be line-of-site. VHF radios use FM (frequency modulation), and the audio clarity is excellent. High-gain antennas can be used to further extend your operating range.

A number of manufacturers offer commercial VHF radios; radios that I've tested include those from Icom, Kenwood, Motorola, and Tad. My preference for these radios are those from Motorola, as they are built very ruggedly, and offer a lot of features while keeping the user interface simple. All of the current models of these radios (except those from Tad) are computer-programmable, which is the method I prefer. Generally, you can take your list of required frequencies to your local radio dealer to get your radio programmed. All Tad and some Kenwood radios have the capability of being user-programmed; this requires a modification to the radio, which then allows the user to hold down a couple of buttons while powering the radio on and entering "program" mode (check your local laws to see if this modification is legal in your area).

Most commercial VHF radios operate between 138-174 MHz, which includes the Amateur portion of the VHF band (144-148 MHz). High-end radios will operate through the entire band; other radios may work in a smaller portion of the band. For instance, Motorola typically offers radios in one of two "bandsplits"; the 138-162 MHz range, and the 146-174 MHz range, although they do have models that can use the entire 138-174 MHz range. Your choice of model is dependent on your assigned frequency and the other frequencies you need to use. In my area, most logging frequencies are between 150-170 MHz; you should endeavor to get your frequency assignment in this range for two reasons: you can purchase the high-bandsplit radio so that you can listen to or communicate with the industrial users, and your antenna will be matched closely to the frequency range you are using (more on matching antennas later). Many amateur radio operators like using commercial VHF radios on amateur frequencies; this is perfectly legal and is a good way of getting a reliable, easy-to-use radio in your truck.

VHF radios require a license and frequency assignment from the federal government. If you wish to have additional frequencies in your radio, you generally require a letter of approval from the licensee of the frequency. License fees are charged on a per-radio basis, not a per-frequency basis. IT IS ILLEGAL TO USE OR POSSESS A VHF RADIO WITHOUT A VALID LICENSE.

High Frequency (HF, aka Short Wave)

HF includes radio frequencies in ranges similar to what are commonly known as "shortwave" bands. Depending on frequency and propagation, HF signals can be heard all around the world. Commercial HF radios, antennas, and antenna tuners are quite expensive, but if you travel in remote areas and need long-range communications, HF is your only option (with the exception of satellite phones). And if the phone system goes down on either end, HF radio frequently is the only means of communications. Prices generally exceed $2500 for the basic radio.

HF communications normally take place on SSB (single-sideband), and the radio is set to either USB (upper sideband) or LSB (lower sideband), depending on the band in use. Frequencies are generally restricted to those set by the ITU (International Telecommuncations Union), and commercial HF radios have these frequencies pre-programmed in memory. Quality radios are manufactured by a variety of companies, including Barrett, Icom, Kenwood, Motorola, and SGC.

HF radios are not commonly used by four-wheelers in our area, although Australia has excellent commercial HF subscriber services for use in the Outback. In Australia, four-wheelers, search and rescue, police and fire services, flying doctors, and many others use these services. HF is primarily intended for long-range communications, so the antennas are typically physically long. Use of HF commercial frequencies requires a license from the federal government.

Please read the notes on HF in the Amateur Radio section (below).

Amateur Radio (Ham)

Amateur (ham) Radio is a unique method of communications, in that it allows users to utilize a variety of bands (ranges of frequencies) from HF to microwave. Ham radio may only be used for non-business communications. If you are at all interested in communications as a hobby, I strongly suggest you get involved with ham radio. Not only will it increase your knowledge of radio communications and electronics, it will allow you to access a vast number of radio types and services.

The scope of Amateur Radio is such that it would be impossible to cover it all in this article; however, I will touch on some equipment that would be of interest of four-wheelers.

VHF: Hams have access to a portion of the VHF spectrum. This means that they can use any frequency in a particular range (144-148 MHz), and are not restricted to certain "channels" like a commercial VHF user. Also, ham radios are "frequency agile", meaning they can be programmed on the fly, without having to be pre-programmed via a computer like a commercial VHF radio. However, many ham radios do have the capability to be computer-programmed as well, which is useful when the preprogramming of numerous frequencies is desired, such as when you're planning on visiting a different area which uses frequencies that are different from your usual area. In addition, many ham operators and ham clubs have set up "repeaters" located in high areas, such as mountain tops. Instead of just talking truck-to-truck they have the capability of talking truck-to-repeater-to-truck; as long as both trucks can "see" the mountain top, they can talk to each other. The height advantage of the mountain-top repeater greatly extends their operating range, and if that particular mountain-top repeater can "see" another mountain-top repeater, they can be linked together. In this fashion, there are numerous Amateur Radio repeater networks which allow hams to talk all over the province or even across Canada on their VHF radios. Also, some repeaters are linked via the Internet, so that world-wide communications via VHF can be realized. A VHF ham radio can be purchased new for $250-$400, depending on features. Dual-band ham radios (which contain both VHF and UHF bands) are available, and typically sell for between $500-$1200. I highly recommend that four-wheelers obtain their Amateur Radio license, even if only for the capability of obtaining and using a VHF radio.

HF: Hams also have access to several bands (ranges) of HF frequencies. Different bands propagate differently, and the band in use will dictate how far the signal will travel. For instance, for me the 80-metre band provides excellent, reliable wide-area coverage throughout BC, whether it's to other hams in the same city, or to hams in northern BC or even into Alberta. Other bands allow Amateur operators to talk to other Amateurs all around the world. An HF ham radio will cost around $1500 and up, depending on features, and some are available with VHF and other bands built in. Quality radios that I've tested and recommend include those manufactured by Icom, Kenwood, and Yaesu. Use of HF bands requires you to pass a Morse Code test, both sending and receiving.

There are other bands and modes (other than voice) that hams are allowed to use; if you're interested, you can do a search on the Internet or join a local Amateur Radio club. Amateur Radio is a whole hobby unto itself, just like four-wheeling, and I'm happy that I'm able to link them together. Canadians interested in Amateur Radio can check out the Radio Amateurs of Canada website, and Americans can check out the American Radio Relay League website.

Due to the complexity of the hobby, prospective Amateur Radio operators must pass a written test and become licensed by their country's federal government before they can possess or operate a ham radio. The test consists of radio theory, electronics theory, and rules and regulations; study guides are available from most Amateur Radio clubs and Amateur Radio stores.

Note: It is illegal to use ham radios on commercial frequencies (ie. outside of the Amateur bands), except in emergency situations.

Mobile telephone


I'd like to take this opportunity to remind you to have a print-out of all of your important phone numbers with you; you can use your computer to print the numbers on a piece of paper the size of a business card, then take it to Staples or somewhere to laminate it. It's useful for when the battery in your hand-held cellular phone has died, or you've lost or damaged your phone, so you can't retrieve the numbers of your winch-equipped friends and you have to walk several miles to a pay phone. Leave it in your wallet. Also, if you have a landline (ie. home phone number), most landline providers (such as Telus) will provide you with a calling card, useful for those occasional pay-phone sorties.

It should be pointed out that ALL mobile telephone communications use two-way radio technology, and in actuality "mobile phones" are really just two-way radios with a telephone-like interface. As such, they can be monitored by people other than those for whom the communication is intended for. While it may be illegal in some areas to monitor certain types of mobile telephone calls, people do monitor them. This caveat also applies to cordless phones.

Cellular

Cellular is a low-power, short-range phone service. Numerous "cell sites" cover a given area, and as you travel around you are seamlessly handed off to the next cell site. Cell sites can be packed close together in a downtown core, or they can be several kilometers apart along a highway between towns. Because of this design, cellular coverage in unpopulated areas is generally non-existant, or marginal if you happen to be close to a highway.

In my area, hand-held cellular phones are by far the most popular form of mobile telephone. They are inexpensive and convenient, and almost everyone I know has one. However, with respect to 4x4 use, there are a number of factors to consider when selecting a phone. Because I only have experience with cellular phones in BC, which has a vast amount of unpopulated land, the following information may not apply to you.

The first issue is the cellular provider (company). In my area, the original cellular providers are Telus Mobility (known as the wireline company), and Rogers AT&T (known as the non-wireline company). These two companies have the best coverage outside the major metropolitan areas. More recent arrivals include Clearnet, Mike (known as Nextel in America), Fido (Microcell), and Bell Mobility. Mike was introduced by Clearnet, but has been purchased by Telus. The main problem with these "newer" companies is that they do not have the infrastructure in place that the older companies have already established. Bell Mobility is the exception; although they are new (in my area), they've been using Telus cell sites. My only beef with Bell is that they have a one-minute minimum call billing, meaning that they only switch to per-second billing after the first minute, and their rate plans aren't any cheaper. Fido is intended for use in major metropolitan centres only; they have no plans to expand their coverage to smaller cities and remote highways. Fido does have the cheapest long-distance rate though. Mike's coverage was similar to Fido's, although they are planning on increasing their coverage to be similar to Telus' coverage over the next several years. Because of their limited coverage areas, we cannot consider service from these "newer" providers for use in our 4x4's. The bottom line here, is that if you want coverage outside of major metropolitan centres, you need to go with either Telus Mobility or Rogers AT&T. As with anything, both networks have their strong and weak points. Sometimes Telus will have coverage where Rogers AT&T does not, and vice versa. When we're out four-wheeling, we generally have phones from both providers, so our chances of getting a signal are greatly improved. It's probably a good idea for you to check to see if there's coverage in the areas you are planning on travelling to; all providers offer a coverage-area map, generally available online as well as from their dealers.

The next thing you need to consider is the type of phone to get. There are two main types of phones we are concerned with here; analog and digital. Analog phones are the old-style phones that were first introduced, like the old Motorola 8000 "brick" phones and the old "fixed-in-car" and "transportable" phones that had a separate handset that plugged into a brain box. The old analog phones could be used with either Telus or Rogers AT&T as both providers used the same technology. Digital phones are a different story. Telus uses "CDMA" technology; CDMA phones have "analog fallback" which allows them to use the old analog system when they can't find a digital signal. This is of importance to us, because we are frequently in fringe coverage areas that have only analog service. Rogers AT&T uses two digital technologies; "TDMA" and "GSM". TDMA is their older system, and TDMA phones have analog fallback. GSM is the standard used throughout the rest of the world, BUT GSM phones are ONLY digital and have no analog fallback. Rogers AT&T says their newer GSM network has the same coverage as their older TDMA network, and it should be noted that all of their new cellsites are GSM only (no TDMA and no analog service). So, if you are getting a new hand-held phone from Rogers AT&T, you should check their TDMA and GSM coverage maps to see which phone type would be best for you. You've probably already guessed that CDMA and TDMA phones are not compatible except in analog mode, so you cannot use a Telus phone on the Rogers AT&T network or vice-versa (except in analog mode). Rogers AT&T will eventually start phasing out their analog equipment in major metropolitan areas (such as Vancouver and Kelowna), but in all likelihood will keep it in rural areas because many subscribers, who are outside of the practical landline coverage and traditional cell site coverage, are using analog 3-watt mobile phones with high-gain directional beam antennas as their primary home phone service. In fringe areas, analog phones have slightly better coverage than digital phones. A good manufacturer of GSM phones is Nokia. Motorola makes some good TDMA and CDMA phones, but some of their phones don't seem to perform as well as their others, so check with your phone dealer before deciding that you want the newest, tiniest flip phone.

I mentioned the fixed-in-car and transportable phones earlier; these analog-only phones are excellent for 4x4 use for several reasons. First, they are analog, and as I've previously mentioned, they will work in fringe areas not covered by the digital networks. Also, they can utilize an external high-gain antenna, which will further extend the range of these phones, both by allowing you to receive a fainter signal, and by giving your transmitted signal more power. And speaking of power, these are 3-watt phones, compared to the 0.6 watt maximum allowed in a hand-held phone. Finally, they use your truck's 12v battery for power, so you don't have to worry about a phone battery dying in the middle of a conversation. On several occasions, I've gotten a usable signal from my transportable Motorola phone in areas where none of the hand-held phones in our group had any service. These phones are typically a "second" phone; ie. your hand-held phone is your primary phone and your fixed-in-car or transportable phone is your secondary or emergency phone. Because of this, you can take advantage of your provider's limited-use or emergency-use rate plans, or you can "share" the usage with your primary phone; ask your provider for more details. Basically, the monthly cost for one of these phones is minimal. The actual cost to acquire one of these phones is also minimal; many people will give these "old clunkers" away because they aren't using them. Good brands of mobile and transportable phones that I've tested are Motorola and Mitsubishi.

Cellular phones can be interfaced to a laptop computer for mobile Internet access.

Note: Don't waste your money on so-called "range extenders" which stick on to your hand-held phone behind the battery, or "RF radiation reducers" which cover your antenna. The so-called range extender will not do anything for you (think about it; it sits next to your metal battery pack!), and the only way for a device to reduce RF energy by covering your antenna is to shield (block) the signal. So, while they may work to reduce the amount of RF energy your brain is exposed to, your range will be drastically reduced. :) As P.T. Barnum said, there's a sucker born every minute. If you ARE concerned about exposing your brain to excess RF energy from your hand-held phone, you can purchase a "portable hands-free kit" which allows you to locate your phone on your belt or somewhere else, through the use of a small plug-in earphone and microphone. This puts the phone (and therefore the antenna) further away from your head. You should be aware that operating your phone on your belt will reduce its range as your body will partially block the signal; for increased range with a portable hands-free kit, you can hold the phone up high so that antenna is both away from your head and body, although if you're doing this, it's not really "hands free" any more. :)
Note: I've called this a "portable hands-free kit" to differentiate it from the traditional hands-free kit kit that gets permanently-mounted in a vehicle.

Autotel

In BC, our landline telephone company is Telus, and Telus offers two additional mobile telephone services, called Autotel and Mobiltel. They are primarily offered to subscribers in remote areas not serviced by cellular. Autotel units resemble a fixed-in-car cellular phone, with used units typically selling for between $100-300 and new units selling for around $1000. The coverage area is broken into wide-area zones, and each zone has a specific "channel" (radio frequency pair) assigned to it. Unlike cellular, Autotel is intended as a medium-range phone service, and subscribers can be many kilometres from the nearest site (repeater). As such, it is well-suited for 4x4 use. Autotel units that I've tested and can recommend are manufactured by Glenayre.

Mobiltel

Mobiltel is the old "radio phone" technology. It's currently being phased out in favour of Autotel, which is unfortunate because practically any commercial VHF radio can be outfitted for Mobiltel use, while Autotel requires a relatively expensive stand-alone unit that can ONLY be used for Autotel. In BC, most of the Mobiltel channels have been taken over by Autotel. In other parts of the world, services similar to Mobiltel are still being offered. This service typically requires an operator to place calls. Any of the radios mentioned in the above Commercial VHF section can be outfitted for Mobiltel use.

Satellite

Everyone who spends any length of time in the bush really needs a satellite phone. The cost of these units are quite expensive compared to cellular phones, with current hand-held models in the $1000 range. Although the prices have become less expensive since they were first introduced, the monthly fee and airtime rates are still quite high, making satellite phone service one of the more expensive methods of back-country communications. However, the advantage of satellite phones is that they can be used practically anywhere in the world, as long as the phone is able to communicate with one of the satellites. Different styles of phones are available; hand-held units similar to a large hand-held cellular phone, or units that are packaged in a briefcase. I have not tested any satellite phones, so I am unable to recommend any particular brand.

Satellite phones can be interfaced to a laptop computer for mobile Internet access.

Antennas


By far the most important piece of communications gear is the antenna. Without a good antenna, even the best radio or phone can become virtually worthless. There are several factors to consider when selecting and mounting an antenna; physical characteristics, gain, mounting type, and mounting location.

Physical characteristics

With antennas, bigger is usually better. A larger antenna can pick up a weak signal better than a smaller antenna, and can allow your transmission to break through the static where a smaller antenna might not be heard. However, antennas must be "tuned" to match the radio frequencies being used, which means that each type of radio or phone requires an antenna of a specific electrical length. I say "electrical" length, because an antenna can be physically shortened through the use of a "loading coil", which gives a physically smaller antenna with the same electrical length as a larger antenna. For example, most people have seen CB antennas. The longest practical mobile CB antenna is the 102" whip. This is the proper length for a "1/4-wave" antenna at CB frequencies. However, this length can be impractical in areas with thick overgrowth, high deadfall, tunnels, etc., and some American 4x4 organizations limit the physical length of antennas for safety reasons. "Base-loaded" antennas are available from such companies as Larsen, Sinclabs, Antenna Specialists, Wilson, and K40; these antennas have a coil at the base to make them electrically the same length as a 102" whip, but in a physically shorter package. Because all of our antennas are liable to be struck by objects such as branches, I highly recommend the installation of a shock spring at the base of the antenna whip. This spring gets installed between the antenna base (or base loading coil) and the whip, and the whip must be shortened by the physical length of the spring, or the antenna will become electrically too long. Bascially, if the spring is 4 inches long, the whip must be shortened by 4 inches.

There are also additional antenna styles not covered in this article. Many undercover law-enforcement vehicles use "disguised" antennas, which are two-way radio antennas disguised as regular AM/FM or cellular antennas. Also available are "radome" antennas, which are ruggedized antennas with a heavy-duty plastic enclosure covering the radiating element. Transit buses and heavy industrial users typically use radomes.

Gain

Generally speaking, "gain" is similar to amplification, in that the more gain an antenna can provide, the stronger the transmitted and received signal will be. For long distances, this can mean the difference between being heard or not. When choosing antennas, the published gain figures can be somewhat misleading. Gain is measured in dB, and a higher figure is better, but different manufacturer's published gain figures are commonly listed as both dBd and dBi. In non-technical terms, the "i" and the second "d" represent two different points of reference. Basically, 0dBd = 2.15dBi. So, at a given frequency, an antenna with rating of 3dBd has more gain than an antenna with a rating of 3dBi.

Generally, an antenna with higher gain will be physically longer than an antenna with lower gain. For VHF use, my in-town antenna (0dBd) is approximately 14 inches long, which allows me to enter underground parking lots and park in my carport. When I'm in the back-country, I switch to a high-gain "5/8 wave" antenna (5dBd) which is approximately 49 inches long, and greatly increases my operating range.

However, a high-gain antenna isn't always desired. The higher the gain, the shorter the "beamwidth" (radiated energy pattern). Think of the beamwidth as a balloon, with a unity-gain (0dBd) antenna displaying the typical round balloon look. As gain increases, the balloon is squeezed from the top and bottom so that it becomes wider and shorter; this has the result of sending more of the signal in a horizontal direction than a vertical direction, which is suitable for wide-open areas with no obstructions. A unity-gain antenna will radiate more energy in a higher vertical pattern and less of a horizontal pattern, suitable for reaching repeaters located on mountain tops or tall buildings. For VHF, a good compromise for general use is a 2.5dBd antenna if you don't want to be swapping antennas. If you're primarily operating simplex (not going through a repeater), then a high-gain (5/8-wave) antenna is desirable.

Mount type

There are two main types of mounts; permanent mounts and magnetic mounts. Magnetic-mount antennas have their base affixed to a magnet, and can be mounted on any flat steel surface such as a roof or hood; this is a good compromise for those who do not wish to drill holes in their vehicles. However, they are not as efficient as a permanently-mounted antenna in the same location, and they can get knocked off by a branch. Permanent-mount antennas have a variety of options; some require drilling a hole in a flat mounting surface such as a roof; some utilize an L-bracket for fender-lip mounting, some clamp to a horizontal bar such as a "West-Coast" style mirror or an ATV rack, and some clamp to the edge of a hood or trunk. Specialized mounting brackets are also available for certain vehicles; for instance, Larsen manufactures a bracket for full-size Dodge pickups, which allows you to mount the bracket using one of the existing fender bolts, and does not require drilling.

Mounting location

Simply put, higher is better. The absolute best place for your antenna is in the middle of a metal roof, if no other metallic objects are close by to cause interference. The next best place is the middle of your hood (or trunk if you have one; the "trunk" is what the British call the "boot"). After that, along the middle of your fender. If you're mounting the antenna by your hood, avoid mounting the antenna too close to your roof supports (A-pillars), as this will cause a signal reflection and will adversely affect your transmission. Basically, you want to surround the base of the antenna with as much flat metal as possible; this is called a "ground plane". A good ground plane is required for optimum operating efficiency, and the direction of the bulk of the ground plane is where most of your signal will go. For instance, if you mount your antenna in the middle of your roof, your signal will be evenly radiated in all directions. If you mount your antenna on your front bumper, most of your signal will radiate towards the rear of your truck.

The mounting location you choose can be based on a number of considerations. If you are frequently in dense brush, an antenna mounted inboard will be less likely to be struck by overgrowth along the side of the trail. If you require medium- to long-range communications, mount the antenna as high as possible.

Two-way radio, Autotel, and Mobiltel

This section includes general notes and recommendations for the various types of two-way radio antennas.

CB: Much of the relevant info on CB antennas has already been covered in the "physical characteristics" section above. In addition, I recommend the use of a steel whip rather than a fibreglass antenna; fibreglass antennas tend to crack or shatter when repeatedly struck by branches at speed. Also, when purchasing a CB antenna, don't bother with "cellular look-alike" antennas; they do not perform nearly as well as a "normal" antenna, and the open coil in the middle of the whip can snag leafy branches. Finally, don't waste your money on a "dual antenna" setup (known as "co-phased" antennas); while the truckers may like the look of dual fibreglass antennas on their mirrors, the antennas must be spaced 102" apart to work properly, and dual antennas can be difficult to "match" (tune to your radio). The money you save by not buying a second antenna and a special coax harness can be used for something useful, like more tools. :)

VHF, Autotel, Mobiltel: These services operate on similar frequencies, so the following notes apply to all three services. The most popular antenna is the 5/8-wave high-gain antenna, which has a small coil at the base and a steel whip approximately 49" long (varies with frequency). I've been talking about "loading coils" in the past which electrically lengthen the antenna; this particular coil is actually a "phasing coil" instead, which is needed because a 5/8-wave element is not resonant and without it, the antenna would be "out of phase" (just in case you were wondering!). A 5/8-wave antenna typically provides a gain of 5dBd. For short-range or in-town use, a 1/4-wave antenna is popular; this antenna is approximately 14" long and does not require a coil (because a 1/4-wave element is resonant). A 1/4-wave antenna has "unity gain" which essentially means 0dBd. Both of these antennas require a proper "ground plane", which is a metallic mounting surface whose radius is equal to a 1/4-wave element, or 14". If your mounting situation is such that an adequate ground plane is not available, ie. a motorcycle, ATV, or fibreglass body, a 1/2-wave antenna can be used. A 1/2-wave antenna resembles a 5/8-wave antenna, but does not require a ground plane, and has unity gain. When used with a ground plane, a 1/2-wave antenna typically provides a gain of 2.5dBd. When operating at VHF frequencies and above, do not transmit when somebody is located within 3 feet of the antenna; doing so can expose them to a dangerous amount of RF energy.

Note: Amateur Radio antennas that work on two or more bands are available, such as VHF/UHF. These antennas typically have two or more coils, and provide less gain than a dedicated single-band antenna. The reason for using one of these antennas is so that your vehicle doesn't resemble a porcupine; for instance, I have one radio in my truck that covers VHF, UHF, and 800 MHz; Larsen makes an antenna that covers all three bands and is the size of a high-gain cellular antenna, so instead of having to mount three separate antennas, I can have a single low-profile antenna that doesn't attract as much attention.

HF: HF antennas are typically very long. Some are similar in size to the 102" steel CB whip, others have a large loading coil in the middle of the whip, and others have a fibreglass lower section with a steel whip on top. Most commercial HF radios come with automatic antenna tuners, thus freeing up the user from having to "match" the antenna to the radio. This is especially advantageous because of the range of frequencies that HF radios cover, which would otherwise necessitate matching the antenna every time the user changed frequencies. With an automatic tuner, the user merely pushes a button and the antenna is tuned within a few seconds. I have this feature on my Kenwood HF radio, and it's great. A friend of mine in the Vancouver area with the same radio once tuned up a garbage-disposal bin on the 20 metre Amateur band, and talked to a ham in California. :)

Cellular

This first section is concerned with antennas for fixed-in-car (mobile) and transportable cellular phones only. On-glass antennas provide the least gain, and can get damaged or even completely removed by branches. In addition, some windows have a metallic coating or tinting which will block the signal. I do not recommend the use of on-glass antennas for 4x4's. One other option is a high-gain fixed-mount antenna. This is an antenna composed of two or more radiating elements; typical units are approximately 12" long and have a coil in the middle of the whip. Higher-gain antennas have two coils in the whip, and are approximately 18" long. When selecting a cellular antenna, ensure that the whip uses "closed coils" and not coils where the windings are visible. Open coils tend to snag branches, and can produce more wind noise than closed-coil whips. If you already own an open-coil antenna, you can slip a piece of heat-shrink tubing over the coil windings to reduce the wind noise.

Don't bother with "shark-fin", or "boomerang" style antennas; they are purely cosmetic and will not outperform or outlast a quality commercial antenna manufactured by companies such as Larsen, Sinclabs, etc.

Another option, suitable for in-camp or mobile command post use, is to use a directional beam antenna, also known as a Yagi. This type of antenna concentrates the signal in one direction, and can greatly extend your coverage area at the expense of portability. A typical cellular beam can be approximately 3 feet long, with 7 elements each measuring approximately 6" spaced evenly along the boom. This antenna requires a mast or similar suitable structure to mount to. Operation is as simple as rotating the antenna until the indicated signal strength on your phone is at maximum. The only caveat here is keep your antenna cable (coax) length as short as possible; signal loss in coax is measured in dB/foot, so the longer the coax run, the more loss you will sustain. At some point, the signal gain from the height of a high-mounted antenna becomes nullified through the signal loss through the longer coax required to mount the antenna at that height. :)

Note: Transportable phones generally come with a short rubber antenna that attaches directly to the phone. If you are using this type of antenna, locate the phone and antenna at least three feet from yourself of any passengers. Remember, these are 3-watt phones, and you definitely do NOT want that much RF energy at 800 MHz so close to your body. This is why hand-held cellular phones are limited to 0.6 watts.

For some hand-held cellular phones, small (1/4-wave) magnetic-mount external antennas are available, and have small-gauge coax and a connector pre-attached from the factory. Phones with an antenna jack (such as current Nokias) typically have a rubber plug blocking the jack; plucking out the plug allows access to the jack and you can enjoy the increased range and clarity an external antenna provides. If you are so inclined, you can attach a high-gain fixed-mount antenna to your external-antenna-capable hand-held phone; you'll probably have to install the coax and connector yourself as they are not commonly available. Some hands-free kits include an external antenna.

Antenna matching

Antenna length is determined by frequency; the higher the frequency, the shorter the antenna. This is why a 1/4-wave antenna for 27 MHz CB (approx. 102") is longer than a 1/4-wave antenna for 150 MHz VHF (approx. 14").

Your antenna must be "matched" to your radio. This requires an "SWR meter" and usually involves cutting the whip to a specific length or adjusting the whip position relative to the coil with a set-screw; higher frequencies require a shorter antenna, and lower frequencies require a longer antenna. For radios using multiple frequencies, the antenna is usually tuned to middle of the band. Do not rely on a manufacturer-supplied "cutting chart" for your whip length; these charts assume your antenna has a perfect "ground plane" (radiating surface) and that there are no nearby metallic objects such as your roof and pillars. If you are installing the antenna on the fender or cowl, make sure that your hood is closed and that nobody is standing close by while you are checking the match. Do NOT attempt to match the antenna if you are not qualified; get someone who knows what they are doing to do it for you. If you do not match the antenna to the radio, you run the risk of some of the outgoing RF energy being reflected back into your radio; this can result in blown "finals" (RF output transistors). A properly-matched antenna will give you the maximum range, both transmitting and receiving. An SWR reading of 1.5:1 or less is generally considered to be acceptable.

Despite what I've mentioned above, I generally follow the cutting chart for matching VHF antennas. However, my VHF antenna is mounted on my roof for maximum range, and I don't have any metallic objects interfering with the match.

Antennas designed for cellular and 800 MHz use are pre-matched from the factory, and generally do not need to be tuned. Dual-band and multi-band Amateur Radio antennas are also pre-matched from the factory.

CB antennas do usually need to be matched; the following procedure can be used for most radio installations, but if you have any doubts, get a qualified service technician to perform the work for you. The usual disclaimers apply; don't attempt it if you aren't totally confident you can do it, and I am not responsible for any damages, injuries, or loss that may occur as a result of your attempt to follow these instructions.

You will need an "SWR meter" designed for CB frequencies, and a short coax patch cable. The patch cable should be as short as possible, ie. 1 or 2 feet. You will also need to access the antenna connector on the back of the CB, so do this BEFORE you permanently install the CB into your dashboard.

Typical SWR meters generally have the following controls: a knob labelled "tune" (or "adjust"), and a switch labelled "forward" and "reflected". There also may be a switch marked "power" with the settings "5w" and "100w" or similar, corresponding to the power scales on the meter. On the actual meter face, there should be a scale with readings similar to "1.0, 1.2, 1.5, 3.0, and then a "red" reading up to the far right-hand side which should be marked "set" or "tune". This scale will tell us the "match", and is a ratio to 1, ie. 1.5:1.

Attach the "input" of the SWR meter to the CB via the patch cable, and attach the antenna to the "output" of the SWR meter. The two connectors on the meter will be marked "radio" (or "input") and "antenna" (or "output"). Turn your CB on, and set it to Ch-19 (the middle of the CB band). Set the SWR meter to "forward" and to "5w". Turn the "tune" knob fully counterclockwise (that's "to the left" for those of you who grew up with digital watches).

Press the push-to-talk (PTT, or "transmit") switch on the microphone. While the PTT is pressed, slowly rotate the "tune" knob clockwise until the needle is at the "set" mark on the scale. Switch the meter to "reflected". This reading is the current "match" of the antenna to the radio at the middle of the CB band; a reading of 1.5:1 or lower is good. Write the reading down. Release the PTT.

Change your CB to Ch-1. Take another meter reading (turn the "tune" knob fully counterclockwise, switch the meter to "forward", press the PTT, rotate the "tune" knob to "set", switch the meter to "reflected"). Write down the value. Release the PTT.

Change your CB to Ch-40. Take another meter reading, and write down the value. Release the PTT.

Compare the values you have written down. If all of the values are 1.5:1 or lower, then I'd advise leaving it alone, as any further tuning will not give you any noticeable performance gain. However, if any of the values are higher than 1.5:1, your system will benefit from properly matching the antenna.

If the match is better (lower) on Ch-1 than Ch-40, then the antenna is too long. If the match is better on Ch-40 than Ch-1, then the antenna is too short. If the match is best at or near Ch-19, and gets worse at both Ch-1 and Ch-40, then it is already optimally tuned.

This procedure can be used for frequencies other than CB; substitute your lowest frequency for "Ch-1", substitute your highest frequency for "Ch-40", calculate the middle of the band (by subtracting the lowest frequency from the highest frequency, dividing that number by two, then adding the result to the lowest frequency), and substitute the calculated middle-of-band frequency for "Ch-19". You will require an SWR meter designed for use with these frequencies; generally meters designed for CB will not work for VHF.

If you have a base-loaded antenna, ie. an antenna with a coil at the base, you can usually adjust the antenna length by loosening the hex (Allen) set-screw in the cone at the bottom of the whip, and moving the whip up or down by a quarter of an inch. Don't cut more than 1/4" off at a time; it's better to be too long and make several cuts than be too short and have to buy another whip. Each time you adjust the antenna, check the match on Ch-1, Ch-19, and Ch-40.

If you have a fibreglass (top-loaded) antenna like a Firestick or Skipshooter, there is usually a rod at the tip of the antenna that can be adjusted up and down by loosening off a hex set-screw then re-tightening it. Sometimes this rod is hidden by a plastic end-cap that is slid over the tip of the antenna. Other fibreglass antennas require you to actually pull off some of the coil windings to adjust the match. To make the antenna shorter, you can pull up a winding (or portion of winding), and cut it off. To make the antenna longer, you can pull (slide) one or more windings up towards the tip, separating them from the main body of windings. For actual instructions on adjusting the length of your particular fibreglass antenna, follow the directions provided by the manufacturer.

If you add a shock spring to your base-loaded or fibreglass antenna, you will have to shorten the antenna by the same amount as the length of the spring (the physical length, NOT the unwound length!).

You do not usually have to tune a 102" whip. Note that these whips come with a spring; if you do not use the spring then the antenna will be too short.

Dual antennas are a pain in the butt to match, and are not covered here, although the basic principles remain the same. Remember that the SWR reading is affected by BOTH antennas. Since I've already stated that I don't recommend dual antennas or fibreglass antennas, please don't send an email asking me how to tune them.

Tip for fibreglass antenna installations: Several people have asked me why their fibreglass antennas had extremely poor performance. EVERY time that I inspected the installation, I found that the plastic insulating washer between the antenna mounting stud and the mounting bracket was missing, thereby grounding the antenna. This can usually be attributed to installer error, although sometimes the washer can crack and fall out, and when the owner notices the antenna has "come loose", he or she merely tightens the antenna to the mount without noticing that the washer is no longer present.

Note: If you are wondering what "SWR" stands for, it's "Standing Wave Ratio".

Coaxial cable

Coaxial cable (coax), or antenna cable, is another important component of your radio system. Always use good-quality coax from manufacturers such as Amphenol, Belden, and Larsen. Coax should have a "stranded" center-conductor, not a solid center-conductor, for vibration-resistance. The "braid" or shield (outer conductor) should be tightly woven, with little if any gaps; gaps mean loss. An ideal coax for 4x4 use is Larsen's "RG-58A/U DigiShield" coax (p/n DS COAX), which features a stranded center-conductor, and a full aluminum/mylar wrap covered by a braid for 100% shielding. This mobile cable is low-loss and high-flexibility, and can be used on all frequencies up to 1000 MHz. It does cost a bit more than the standard RG-58A/U coax, but with my communications setup I think it's worth it. This cable is actually manufactured by Belden (p/n YR22688). I should mention that coax with a solid center-conductor actually exhibits less attenuation (signal loss) than coax with a stranded center-conductor, but the flexibility that the stranded center-conductor offers outweighs the relatively minor loss.

As noted earlier, never use crimp-type coax connectors; crimps can fail due to vibration. Always use a quality solder-type connector such as those made by Amphenol.

Installation

General considerations

As with anything, your radio should be installed correctly the first time. Our radios need to work when we need them; having to troubleshoot a radio problem at the side of a trail, in the middle of a rainstorm at midnight, is not something we want to have to do. Careful consideration of component placement should be taken with respect to safety, convenience, and ergonomics.

Power source

Power should be run right from your battery. This will help eliminate ignition, alternator, windshield-wiper, and other "brush" noise, which manifests itself as static or whine, and can prevent you hearing distant stations. Another advantage of taking power from the battery and not an ignition- or accessory-switched circuit in your fuse box is that if you need to switch your ignition off, or cannot locate your keys, you can still use your radio to call for assistance.

Your power cable should be fused as close as possible to the power source, which means that it should be located right at the battery. Failure to do this can result in a fire if the power cable gets shorted to ground (ie. a metal body or frame), with the entire section of wire between the power source to the fuse going up in smoke. Ensure that your fuse has the correct rating, and always carry a few spares.

The power cable should be routed through bulkheads and panels with the use of rubber grommets; this will prevent sharp metal and plastic edges from cutting through the cable and causing a short. Whenever possible, cover the power cable with plastic convoluted tubing to prevent chafing. When routing the cable under the dash, make sure that it doesn't interfere with the brake and throttle pedals, parking brake lever, and heater controls (this applies to the coax (antenna) cable as well).

If you aren't using the factory-supplied power cable, you should be using wire of a heavy-enough gauge to allow enough current to reach the radio. Also, a heavier-gauge cable will reduce noise.

Never use barrel or Scotch-lock-type crimp connectors; they are unreliable in our 4x4's due to the constant jarring and vibration our vehicles are subject to. Instead, the insulation can be stripped back, and the "tap" wire can be wrapped around it and soldered into place. The connection to the battery and ground can utilize ring-type crimp connectors, provided that you solder the connectors after crimping them; please read the article on installing crimp connectors for the correct way to do this.

Try to use heat-shrink tubing instead of electrical tape to cover your wiring connections; tape has a nasty habit of unravelling and leaving a sticky residue. Heat-shrink is more durable, and makes for a professional-looking installation.

Permanent mounting

A permanently-mounted radio is more reliable than a temporarily-mounted radio; it's not being moved all the time so the wires and connections aren't being pulled or stretched, and it's not subject to sliding around or being dropped on the floor. Most radios come with some sort of mounting bracket; this is useful if you wish to mount your radio under the dashboard or on the transmission hump. Custom installation sometimes requires a bracket to be fabricated; I usually use aluminum as it's easy to work with. If you have the space, and your radio is DIN-sized or smaller, you can mount it in your dash beneath your stereo.

Ensure that the radio and microphone placement does not interfere with the operation of shifters, airbags, seats, passengers, and other moving objects. The radio should be within arms reach, and the display should be easily visible. The microphone should also be mounted within arms reach without you having to change position or "reach" for it, and located such that it can be easily removed and replaced without looking for the microphone hanger; make sure the microphone cable doesn't interfere with the operation of the shifters, parking brake, etc.

Rally drivers wearing helmets can benefit from in-helmet headsets; they can be triggered by VOX (voice-operated transmit) or pushbutton, and don't require the driver to use a hand to hold a microphone. This is generally a custom solution, which your radio shop can set up for you.

Temporary mounting

I don't recommend temporary mounting, but sometimes it's necessary in certain situations, such as in open-top vehicles whose owners are worried about theft. One method of temporary mounting that I've used is to mount the radio into a military-surplus ammo box; you can use the factory mounting bracket, and the microphone, power cable, spare fuses, and magnetic antenna mount and coax can be placed into the box during storage. Most vehicles come with cigarette-lighter power plugs, and you can use this connector as your 12v power source. Even though the cigarette-lighter power connector is fused, you should also have a fuse in your power cable. Depending on the shape of the container, it can be seat-belted into place, or jammed in place behind a seat. Remember that any loose items in your cab are likely to contact your body in the event of a roll, so you should endeavor to fasten down your temporary radio while in transit.

An alternative to a temporarily-mounted radio is through the use of a "slide bracket". This is a two-piece bracket, with one end bolting to the top of the radio, and the other end mounting beneath the dash. This arrangement allows you to quickly remove the radio when your vehicle is left unattended. I've tested commercial slide brackets manufactured by Gamber-Johnson; they are well-built and are of much better quality than the cheapie CB slide-brackets sold by mass-retailers and truck stops. Another advantage of the slide-bracket system is that you can purchase additional mounts, which allows you to move your radio between vehicles. Some VHF and CB radios come with a slide bracket built into the case.

Accessories


Generally, the above-described basic communications equipment will suffice. However, accessories are available which can increase intelligibility and make your life easier.

TWO-WAY RADIO

Ear mike

In conditions with high ambient noise, your voice is frequently unreadable, and many communicators attempt to counter the background noise by yelling into their microphones, which only distorts their voice at the other end. When you speak, you can hear yourself through the vibrations of the bones in your ear. The ear mike also works by picking up the vibrations in your ear, instead of vibrations from your mouth. The advantage to this is that only your voice is transmitted, without the background noise. An ear mike resembles an ear plug, and combines both a speaker (earphone) and microphone in one unit. Ear mikes are generally only available for professional-grade VHF and UHF hand-held radios.

External speaker

Primarily for permanently-mounted two-way radios, an external remote speaker will plug into a jack in the back of the radio and can improve received audio through the use of a larger speaker, or through the ability to mount the remote speaker in a location that allows the speaker to project sound in an unobstructed path to your ears. External speakers are especially useful if your two-way radio has a small speaker on the bottom of the radio, which projects the sound into your floor. If you're purchasing an external speaker, a good size to look for is a 4" round speaker. As with anything, there are "cheap" speakers and "good" speakers. Amplified speakers are also available for high-noise locations; they will require a power source, usually 12vDC. I've observed that some amplified speakers emit a faint but constant hum or buzz, which can be annoying in a quiet environment.

Speaker-mike

Primarily for hand-held two-way radios (walkie talkies), a speaker-mike allows you to carry the radio in a chest pack, belt-hung carry case, or tactical vest. A speaker-mike has a speaker, microphone, and push-to-talk (PTT) switch, at the end of a coiled cord, along with a spring-loaded clip which can be fastened to your clothing. Instead of having to handle the entire radio, which can be inconvenient, all you have to worry about is the small speaker-mike. Some speaker-mikes have an earphone jack in them. Most radio companies manufacture their own speaker-mikes, and cheaper aftermarket units are also available. Some speaker-mikes also have an antenna mounted on the top of the housing; this gets the antenna away from your body if the radio is on your belt, as your body will block the radio signal. These mikes will have a straight cord, as a coiled cord is not compatible with the antenna cable.

CELLULAR PHONES

Hands-free kit

In many areas, using a cellular phone while driving is illegal except if used with a hands-free kit. Basic hands-free kits allow you to plug in your cellular phone, and provide you with a visor-mounted microphone, and an external speaker that you can mount under your dash or to your center console. This lets you talk without having to handle your phone. Higher-end kits also include an external antenna to increase your range, and will also charge your cell-phone battery at the same time. Hands-free kits are available for most hand-held cellular phones.
Note: Do not mount your speaker so that it points directly at the microphone; doing so may cause "feedback" at higher volumes.

Related equipment


While not really part of 4x4 communications, I've included these topics because I frequently get asked about them.

Global Positioning System (GPS)

GPS units use a network of orbiting satellites to display your exact location in latitude and longitude. This actually only requires two satellites; if a third satellite can be "seen" by the GPS unit's antenna, the GPS unit can also display your elevation. When purchasing a GPS unit, make sure it has a "12 parallel-channel receiver"; this is the current standard and I believe all current units have it, but some older units do not.

Most GPS units have a data port that allows you to interface it to a computer; we use this in conjunction with mapping software to plot our exact trip on a map. This software also allows us to mark "waypoints" (points of interest), and enter a note for future reference. For instance, we can record the exact location of an abandoned mine or an unmarked fork in the road, with the appropriate comments. Years later, we'll still be able to find that exact spot. You don't need a computer to mark waypoints, but interfacing the GPS unit to a full-colour map with a large display and a real keyboad makes things so much nicer, and allows you to use an older or less-expensive GPS that doesn't have a large memory capacity.

Another desirable features to look for is a jack for an external antenna. This allows you to purchase an "active" antenna (high-gain), and locate that antenna on the roof of your truck instead of using the built-in antenna inside the cab, and worrying about your roof blocking the satellite signal.

Other desirable features are the ability to rotate the display to either a vertical or horizontal orientation, waterproofing, floatation, large buttons, a jack for external power, and at least 500 user waypoints.

Some GPS units come with fancy features such as street maps, electronic compass, and voice prompts, but the reality is most four-wheelers don't need these extras, and don't need to pay for them. In fact, for users who are planning only to interface their GPS to a computer, you can purchase a "GPS engine" which is an external antenna with the GPS electronics contained inside it; it has no display or controls, and a single cable allows you to connect it to power, ground, and computer.

As mentioned in the FRS section, Garmin has come out with units called "Rino" that have both GPS and FRS radio functions. This allows the radio to send it's exact position to the other radios, and can be of help if one of your group is lost but is still within radio range. The fancier Rino units can display a map that shows where all of the other Rino units in your group are located.

Scanners

"Scanners" are radio receivers that can quickly scan a range of frequencies, or a pre-programmed bank of frequencies. They will continuously scan the frequencies until audio is heard, and will then stop on that frequency for a predetermined amount of time, then will resume scanning again.

This is useful for monitoring frequencies in use by logging trucks, emergency services, aircraft, weather forecasts, and pretty much anything that is transmitted via a two-way radio. For instance, road frequencies are posted at the start of most logging roads; if you enter those frequencies into your scanner you'll be able to monitor where the logging trucks are on that road.

The hobby of scanning can be quite involved, depending on what you are attempting to monitor, and, like Amateur Radio, in-depth coverage is beyond the scope of this article. However, like our other communications gear, a good antenna is a vital part of the monitoring hobby. Larsen makes an inexpensive tri-band antenna that covers VHF, UHF, and 800 MHz, the three most-common bands in use by emergency services and commercial users, and this antenna is an excellent, unobtrusive unit that resembles a high-gain cellular antenna. If most of the frequencies you wish to monitor are VHF, you can use a high-gain VHF antenna for increased range, but UHF and 800 MHz performance will be degraded.

Desirable features include at least 300 programmable channels, 10 or more scan banks, a scan speed of at least 50 channels per second, alphanumeric tagging, data port for interfacing to computer, and coverage from 30-54 MHz low-band VHF, 118-136 MHz AM aircraft, 136-174 MHz VHF, 380-512 MHz UHF, and 800-1000 MHz.

In my local area, the Vancouver area of BC, an EDACS-capable Uniden TrunkTracker scanner is needed to track most of the local emergency services. However, the police forces utilize a different modulation method (known as IMBE) via a proprietary add-on board, and cannot be monitored via scanner. Uniden does manufacture a "digital board" that can be added to their "digital-capable" TrunkTracker scanners; this board is APCO-25 compatible, and will not allow you to monitor IMBE. APCO-25 is a "digital" standard used throughout America.

Note: Current scanners available to the general public in America have the cellular-telephone portion of the 800 MHz band blocked. The reason for this is the American "Electronic Communications Privacy Act" of 1986 (ECPA(1986)), which prohibits the monitoring of cellular telephone communications in America; partially a result of extensive lobbying by cellular telephone providers who were attempting to convince the American public that cellular telephone conversations were "private". Qualified American users such as government agencies and cellular-telephone providers are able to purchase "unblocked" scanners. Canada has no such restriction, and we can still purchase scanners that cover the cellular-telephone portion of the 800 MHz band.

Communicating effectively


When communicating, it's important that the person you are communicating with knows what you're talking about. This is especially vital in an emergency situation when seconds can save a life.

Communications are most efficient if you speak in plain language. What this means is, don't use codes, abbreviations, local slang, or CB jargon. Remember that the person you are speaking to may not understand the terminology, or even worse, may misinterpret what you're saying and not even question you about it.

Say only what needs to be said. Relay the information in a consise manner; don't be wordy, don't say "uhh" or "um", and keep your transmissions brief. If the information you are relaying will take a while to recite, periodically stop transmitting for a few seconds in the event the person you are speaking with requires clarification, or another station has higher-priority traffic.

In an emergency situation, when the adrenaline is pumping and there's a high ambient noise factor, many people make the mistake of yelling into the microphone. This does not work! All it does is cause distortion, and the person at the other end will not be able to understand you. Remain calm, and speak clearly in a normal voice, like you would if there was no external noise present. Maintain a distance of one to three cm's between your mouth and the microphone.

When reciting an alphanumeric string, it's best to break it up into groups of threes, saying the letters with phonetics. For instance, if you need to pass on the string "12345678ABC", recite it as "1 2 3, 4 5 6, 7 8 alpha, bravo charlie". This makes it easier for the person receiving the message to write the string down.

Phonetic alphabet

If necessary, you can use the phonetic alphabet to assist in spelling out letters. The alphabet below is the International phonetic alphabet, used all over the world except in America. For some reason, Americans have their own phonetic alphabet, but if you use the International version, anyone anywhere will be able to understand you. Memorize it so that it becomes second nature; you won't have time to look it up when you're calling for help on the trail. Don't be afraid to use phonetics when speaking to an emergency dispatcher; it's part of their training. Finally, don't substitute phonetics, as that only tends to confuse the person you're talking to.

A B C D E F G H I J K L M

Alpha Bravo Charlie Delta Echo Foxtrot Golf Hotel India Juliet Kilo Lima Mike

N O P Q R S T U V W X Y Z

November Oscar Papa Quebec Romeo Sierra Tango Uniform Victor Whiskey Xray Yankee Zulu

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