Why Every Prepper and Hunter Needs a Ham License (Not a GMRS)
8,668 words, 46 minutes read time.
Let’s rip the band-aid off right now. You have spent thousands of dollars on rifles, optics, plate carriers, freeze-dried food, water filtration, and enough ammo to make your closet floor sag. You have a bug-out bag that would make a YouTube prepper channel proud. You have practiced fire-starting with a ferro rod in the rain. You have land-nav skills with a map and compass. You feel ready. But if someone asks you what your communications plan is when the cell towers go dark, when the internet is a memory, when power grids are down and you are 30 miles from the nearest paved road, most of you will hold up a blister-packed GMRS radio from Amazon and say, “I’ve got comms covered.” No, you do not. Not even close. That GMRS radio is a tool with a role, and it fills that role adequately for what it is — short-range, line-of-sight communication between family members or a small group within a few miles. But calling it a communications plan is like calling a pocket knife a survival kit. It is one small piece of a much larger picture, and if it is the only piece you have, you are building your entire emergency communications strategy on a foundation that will crack the moment real adversity shows up. The uncomfortable reality is that the prepper and hunting communities have a massive blind spot when it comes to communications, and that blind spot exists because GMRS is easy, it is marketed aggressively, and it does not require you to learn anything. Getting a GMRS license is literally filling out a form and paying a fee. No test. No demonstrated knowledge. No understanding of propagation, antenna theory, or emergency protocols. And that low barrier to entry has created an entire subculture of people who believe they are communications-capable when they are functionally illiterate in the one discipline that matters most when everything else fails.
This post is going to lay out, in plain and direct terms, why every serious prepper and hunter needs to stop leaning on GMRS as a primary comms solution and go get an amateur radio license. Not because ham radio is trendy. Not because it is some elitist hobby for old guys soldering in their basements. Because when the grid goes down, when the repeaters lose power, when you are in a drainage in the backcountry and your hunting partner is on the other side of a ridge, amateur radio is the only communications capability that gives you real flexibility, real range, and real options. Everything else is a toy by comparison.
What GMRS Actually Gives You (And Where It Hits a Wall)
GMRS Range, Power, and Repeater Limitations in Real-World Terrain
Before going any further, let me be clear about something — this is not a post about trashing GMRS. GMRS has a legitimate purpose. It is a UHF radio service operating on frequencies around 462 and 467 MHz, it allows up to 50 watts of power on certain channels, and it gives users access to a small number of repeater frequencies. For a family camping trip, a convoy of vehicles on a road trip, or communication between a house and a barn on a rural property, GMRS works fine. It is simple, the radios are affordable and widely available, and the license covers your entire immediate family for one fee. Within its design envelope, it is a perfectly acceptable tool. The problem is that most preppers and hunters are not operating within its design envelope when they actually need comms the most. They are operating in exactly the conditions where GMRS falls apart.
UHF frequencies, by the physics of radio propagation, behave in a very specific way. They travel primarily by line of sight. They do not bend over hills. They do not diffract well around mountains. They get absorbed and scattered by dense foliage. They are excellent in flat, open terrain or urban environments where repeaters are plentiful and closely spaced, but the moment you put a ridge, a mountain, or a thick stand of timber between you and the person you are trying to reach, your effective range collapses. That 50-watt GMRS mobile radio that the manufacturer claims can reach 30 or 40 miles under ideal conditions will give you maybe two to five miles in mountainous terrain on simplex, and that is being generous. A handheld GMRS radio at five watts in the same terrain might give you a mile or less. This is not a design flaw in the radio. This is physics, and no amount of money spent on a fancier GMRS unit will change the fundamental behavior of UHF signals in rough country. The standard workaround for this limitation is repeaters — elevated stations that receive your signal and retransmit it at higher power and better elevation to extend range. And GMRS does allow repeater use on certain channel pairs. But here is the critical question that almost nobody in the prepper community asks: who owns and maintains those repeaters, and what happens to them when the grid goes down? The answer, in the vast majority of cases, is that GMRS repeater infrastructure is sparse, privately owned, often poorly maintained, and almost never equipped with backup power systems designed to survive an extended grid-down event. In rural and wilderness areas — exactly the places where preppers plan to retreat and hunters actually operate — GMRS repeater coverage is often nonexistent. You are on simplex, you are on UHF, and you are at the mercy of terrain. That is the reality.
The FCC Licensing Gap — GMRS Privileges vs. What You Actually Need in a Crisis
The GMRS license itself tells you a lot about what the FCC thinks this service is for. It is a no-test license. You pay $35, fill out the form on the FCC Universal Licensing System, and you are good for ten years. There is no examination of your knowledge of radio operations, propagation, emergency procedures, or electrical safety. The FCC designed GMRS as a personal and family communication service — the regulatory equivalent of a slightly more capable walkie-talkie. And the privileges reflect that purpose. You get 22 channels. You get UHF only. You cannot operate on HF frequencies, which means you have zero ability to communicate beyond your immediate local area without infrastructure. You cannot operate on VHF, which means you lose the propagation advantages that the two-meter band offers in varied terrain. You cannot legally build or modify your own equipment under GMRS rules in any meaningful way. You cannot use digital modes like JS8Call or Winlink that enable text-based communication and off-grid email over thousands of miles. You cannot participate in APRS, which allows real-time GPS tracking and position reporting. You are locked into a narrow set of frequencies with a narrow set of capabilities, and when those capabilities are insufficient — which they will be in any serious emergency or any real backcountry scenario — you have no fallback, no flexibility, and no options. That is the licensing gap, and it is enormous.
Why Amateur Radio Is the Gold Standard for Off-Grid and Emergency Communications
HF, VHF, and UHF — Understanding the Full Spectrum Advantage of a Ham License
The amateur radio licensing structure is built on a completely different philosophy than GMRS. The FCC requires you to demonstrate actual knowledge to earn your privileges, and in return, those privileges are vast. Even the entry-level Technician license — the easiest of the three ham license classes — unlocks a world of capability that GMRS cannot touch. With a Technician license, you gain full access to all amateur frequencies above 30 MHz, which includes the enormously popular and useful two-meter (144–148 MHz) and 70-centimeter (420–450 MHz) bands. The two-meter band alone is a game-changer for both preppers and hunters because VHF signals behave differently than UHF in terrain. Two-meter signals, while still largely line-of-sight, diffract and bend around obstacles somewhat better than the UHF frequencies used by GMRS, and the amateur two-meter band has an absolutely massive repeater infrastructure across the United States — thousands of repeaters, many of which are maintained by dedicated amateur radio clubs with battery backup, solar power, and generator systems specifically designed to stay operational during emergencies. The difference in repeater infrastructure between GMRS and amateur radio is not marginal. It is an order of magnitude. Beyond VHF and UHF, the Technician license also grants limited privileges on certain HF bands, including portions of the 10-meter band with voice privileges and segments of 80, 40, and 15 meters with CW (Morse code) and data modes. But the real power of HF opens up with the General class license, which is one step above Technician and requires a second 35-question exam. With a General license, you gain access to large portions of every HF band from 160 meters through 10 meters, and this is where amateur radio enters a completely different dimension of capability. HF signals do not rely on line of sight. They bounce off the ionosphere, a phenomenon called skywave propagation, and this means that a General-class operator with a hundred-dollar radio and a wire antenna strung between two trees can communicate hundreds or thousands of miles with zero infrastructure — no repeaters, no internet, no cell towers, no satellites, nothing but the ionosphere and the transmitted signal. That is not theoretical. That is what ham operators do every single day, and it is what they have done in every major disaster in modern history when all other communications systems have failed.
The concept that separates amateur radio from every other personal communications option is this: spectrum flexibility. A ham operator is not locked into 22 channels on a single band. A ham operator can choose the right frequency for the right conditions at the right time. Need to talk to your buddy two miles away on a trail? Use two meters simplex. Need to hit a repeater 40 miles away to relay a message? Use two meters through the repeater system. Need to reach someone 200 miles away when all the repeaters are down? Use 40 or 80 meters with NVIS — Near Vertical Incidence Skywave — a propagation technique where you aim your HF signal nearly straight up so it bounces off the ionosphere and comes back down within a few hundred miles, providing regional coverage with no infrastructure whatsoever. Need to reach across the country or across the ocean? Use 20 meters or 17 meters during the right part of the solar cycle and work stations thousands of miles away. No other personal radio service on the planet gives an individual this kind of range and flexibility, and the license to access all of it costs you nothing but study time and a small exam fee.
Mesh Networks, Digital Modes, and APRS — Capabilities GMRS Cannot Touch
Raw range and spectrum access are only part of the story. The amateur radio ecosystem has developed an entire universe of digital tools and techniques that transform a simple radio into a full communications platform, and none of these capabilities are available to GMRS users. Start with APRS — the Automatic Packet Reporting System. APRS is a real-time digital communications system that transmits GPS position data, short text messages, weather information, and telemetry over the two-meter band at 144.390 MHz in North America. When you are running APRS, your radio is periodically broadcasting your exact GPS coordinates, and those coordinates are picked up by digipeaters and internet gateways that plot your position on a live map accessible at aprs.fi. For a hunter in the backcountry, this is not a novelty — it is a genuine safety system. Your family, your hunting partners, or your emergency contacts can see exactly where you are in real time without you making a single voice call. If you go down with an injury, if you get lost, if weather closes in and you need to shelter, your last known position is on the map. Search and rescue teams have used APRS data to locate missing persons, and the system works in areas with zero cell coverage because it runs entirely on amateur radio infrastructure and does not require the internet to function at the field level. You cannot do this with GMRS. Period.
Then there is JS8Call, a keyboard-to-keyboard digital messaging mode designed specifically for weak-signal HF communication. JS8Call is built on the WSJT-X engine, the same technology behind FT8, which is famous for being able to decode signals far below the noise floor — signals that you literally cannot hear with your ears. JS8Call takes that weak-signal capability and turns it into a practical store-and-forward messaging system. You type a message, your radio transmits it as a digital signal on HF, and a station hundreds or thousands of miles away decodes it and can relay it further. This works with radios running as little as five watts into simple wire antennas, and it functions in conditions where voice communication would be completely impossible. For a prepper who needs to send and receive information during a grid-down scenario — weather reports, coordination messages, welfare checks, situational updates — JS8Call is an extraordinarily powerful tool that requires nothing but a radio, a computer or tablet, and a sound card interface. The total cost of this setup can be under $300, and it gives you text-based communication capability across continental distances with no infrastructure whatsoever.
Winlink takes this concept even further. Winlink is a worldwide radio email system that allows amateur operators to send and receive email over HF, VHF, and UHF radio links. When the internet is down, when cell networks are overwhelmed or destroyed, Winlink allows you to compose an email on a laptop, transmit it via radio to a Winlink gateway station, and have that email delivered to any standard email address on the internet — or to another Winlink radio station if the internet is completely unavailable. During Hurricane Maria in 2017, when Puerto Rico lost virtually all communication infrastructure, amateur radio operators using Winlink were among the only people on the island who could send messages to the outside world. Hospitals used ham operators with Winlink to transmit patient lists and supply requests. Emergency management agencies relied on Winlink traffic when their own systems were nonfunctional. This is not a hypothetical capability. This is documented, verified, real-world performance in one of the worst natural disasters in American history. And it is a capability that exists exclusively within the amateur radio service. GMRS does not support Winlink. GMRS does not support JS8Call. GMRS does not support APRS. GMRS does not support any digital mode beyond some limited text messaging on certain commercial radios. The capability gap between the two services is not a crack — it is a canyon.
The Prepper Communications Failure Most People Do Not See Coming
Why Repeater-Dependent Plans Collapse After 72 Hours
Here is a scenario that plays out with depressing predictability in every major disaster, and it is one that the prepper community needs to internalize deeply. A significant event occurs — hurricane, earthquake, ice storm, wildfire, cascading grid failure. Cell towers go down almost immediately, either from direct damage, loss of backhaul connectivity, or because backup batteries drain within four to twelve hours when commercial power is lost. Most cell tower battery backup systems are designed to last eight to twelve hours under normal load, and during a disaster, load spikes dramatically as everyone in the affected area tries to call or text simultaneously. Within the first day, cellular communications in the affected zone are largely nonfunctional. People who planned on using cell phones for emergency comms are already out of options. Now the GMRS users step up, and for the first 24 to 48 hours, they feel validated. Their radios work on simplex for short-range communication, and if they are lucky, a local GMRS repeater is still operational on backup power. They can talk to their family members and nearby group members within a few miles. It feels like the plan is working.
Then hour 48 hits, then hour 72, and reality sets in. The GMRS repeater, if it was running on a battery backup, is dead. The repeater owner either evacuated, has no way to refuel a generator, or the repeater site itself is inaccessible due to road damage or fire. Without the repeater, GMRS range collapses back to simplex — a few miles at best in anything other than flat, open terrain. The GMRS users now have no way to communicate beyond their immediate vicinity. They cannot reach anyone outside the disaster zone. They cannot send messages to family in other states. They cannot access weather information, coordinate with other groups, or request assistance from anyone beyond shouting distance. Their entire communications plan has evaporated in three days, and they are now functionally isolated. This is not an exaggeration. This is exactly what happened in Puerto Rico after Hurricane Maria, in New Orleans after Hurricane Katrina, in large sections of the Gulf Coast after Hurricane Michael, and in Paradise, California, during the Camp Fire. In every one of these events, the communications infrastructure that most people relied on — cellular, landline, internet, and low-tier radio services — failed within hours to days. And in every one of these events, the communications backbone that survived and provided critical information flow was amateur radio.
Real-World Disaster Communications — Lessons from Hurricanes, Wildfires, and Grid-Down Events
The track record of amateur radio in disaster communications is not anecdotal — it is extensively documented by FEMA, the Government Accountability Office, the American Red Cross, and the National Weather Service. After Hurricane Maria devastated Puerto Rico in September 2017, the island lost 95 percent of its cell sites and virtually all internet connectivity. Amateur radio operators, organized through ARES (the Amateur Radio Emergency Service) and working in coordination with FEMA, the Salvation Army, and local emergency management, provided the primary communications link for weeks. They transmitted health-and-welfare messages for thousands of families, relayed supply requests from hospitals and shelters, provided damage assessment reports to emergency managers, and maintained Winlink email gateways that served as the only digital messaging capability on significant portions of the island. The GAO report on the federal response to the 2017 hurricanes specifically documented the role of amateur radio in filling communications gaps that no other system could address.
Hurricane Katrina in 2005 produced a similar pattern on an even more chaotic scale. The storm destroyed or disabled over 1,000 cell sites across the Gulf Coast and knocked out landline service to three million customers. Amateur radio operators self-deployed and were activated through ARES and RACES (Radio Amateur Civil Emergency Service) to provide communications for shelters, hospitals, law enforcement agencies, and the Red Cross. In many areas of coastal Mississippi and eastern Louisiana, amateur radio was the only functional communication system for the first five to seven days after the storm. The operators who made this possible were not using simple handheld radios on a single UHF frequency. They were running HF stations with emergency power, VHF repeaters with generator and solar backup, and digital modes including Winlink and packet radio to move structured message traffic across hundreds of miles. This level of capability requires the knowledge, licensing, and equipment that only amateur radio provides.
The 2018 Camp Fire in Paradise, California, presents another instructive case. The fire moved so fast that evacuation communications collapsed almost immediately. Cell towers burned. Power lines came down. The normal communications infrastructure that residents and first responders depended on was destroyed in hours. Amateur radio operators in the surrounding area activated immediately, providing situational awareness, relaying evacuation information, and helping coordinate search and rescue efforts. The Skywarn program, a joint effort between the National Weather Service and the amateur radio community, provided real-time ground-truth weather observations during the fire that supplemented data from official weather stations — many of which were also destroyed or inaccessible. And during the 2021 Texas grid failure, when millions of Texans lost power for days in freezing temperatures, amateur radio operators maintained communication networks that helped coordinate welfare checks and resource distribution in areas where cell service was degraded or unavailable.
The pattern across all of these events is consistent and undeniable. When infrastructure fails — and in a serious disaster, infrastructure always fails — the communications service that survives is the one that does not depend on infrastructure. Amateur radio, particularly on HF, is that service. GMRS, by its very design, is infrastructure-dependent for anything beyond short-range simplex communication, and short-range simplex communication is not a plan. It is a hope.
The Hunter’s Case for Ham Radio — Why Backcountry Comms Demand More Than GMRS
Terrain, Distance, and the Physics of UHF in Mountain Country
Shift the context from disaster preparedness to backcountry hunting, and the case for amateur radio over GMRS becomes even more stark. Consider the typical western big game hunt — elk in the mountains of Colorado, Montana, or Idaho, mule deer in the canyons of Utah or Nevada, moose in the river drainages of Alaska. These are environments defined by extreme terrain: steep ridges, deep valleys, dense timber, and distances between hunting partners that can easily stretch to five, ten, or twenty miles depending on the unit and the strategy. UHF signals, which is all GMRS gives you, are brutally punished by this kind of terrain. A GMRS handheld at five watts will not reliably cross a single major ridge in the Rocky Mountains. Even a GMRS mobile at 50 watts, mounted in a truck at a trailhead, will struggle to reach a hunter two drainages over because there is simply no line-of-sight path for the UHF signal to follow. The signal does not bend. It does not diffract meaningfully around a granite ridgeline. It hits the mountain and it stops. Hunters who have experienced this know exactly what it feels like — you are keying up, calling your partner, hearing nothing but static, and realizing that your fancy GMRS radio is functionally useless in the terrain you are actually hunting in.
VHF, specifically the two-meter amateur band, performs measurably better in these conditions. The longer wavelength of VHF signals gives them a slight but meaningful advantage in diffracting around terrain features and penetrating vegetation compared to UHF. This does not mean two meters is magic — it is still largely line-of-sight — but the difference in practical performance in mountain and forest terrain is noticeable, and in a situation where an extra half-mile or mile of range means the difference between reaching your partner and not reaching them, that difference matters. More importantly, the amateur two-meter band has vastly more repeater coverage in rural and mountainous areas than GMRS does. State and regional amateur radio clubs have been building and maintaining mountaintop repeaters for decades, and many of these repeaters are solar-powered, battery-backed, and specifically sited on high points to provide maximum coverage of backcountry areas. A hunter with a Technician license and a two-meter handheld can often hit a ham repeater from a drainage where a GMRS radio gets nothing, and through that repeater, reach a partner, a base camp, or even a phone patch to call for help.
APRS Tracking, Winlink Check-Ins, and Emergency Beaconing for Backcountry Hunters
Beyond voice communication, the digital capabilities of amateur radio offer backcountry hunters safety tools that are genuinely life-saving and that simply do not exist in the GMRS world. APRS tracking, as discussed earlier, allows a hunter carrying a small APRS-capable transceiver — or even a lightweight tracker like the Mobilinkd TNC paired with a two-meter handheld — to broadcast GPS position reports that are received by digipeaters and plotted on a live map. Your hunting partner at base camp, your spouse at home, or a search and rescue coordinator can see your track and your current position in real time. If you are injured and cannot make a voice call, your last APRS position gives rescuers a starting point that is accurate to within meters. This is not a replacement for a PLB (Personal Locator Beacon) or a satellite communicator like an InReach, but it is a complementary system that works on a completely different infrastructure, provides two-way messaging capability that a PLB does not, and costs nothing to operate after the initial equipment purchase because there are no subscription fees. Compare that to satellite communicator subscriptions that run $30 to $50 per month and you begin to see the long-term value proposition clearly.
Winlink provides another layer of safety for extended backcountry trips. A hunter on a ten-day horseback elk hunt in a wilderness area with zero cell coverage can use a lightweight HF radio and a Winlink gateway to send daily check-in emails to family members. Not text messages through a satellite service at a dollar per message. Full emails, with the ability to receive replies, sent over radio waves that travel hundreds of miles to a gateway station and then route to any email address on the internet. This capability exists right now, it works, it has been proven in the field by countless operators, and it requires nothing but a General-class amateur license, a portable HF radio, a wire antenna, and a laptop or tablet running the Winlink Express software. The entire setup fits in a small dry bag and weighs a few pounds. For a hunter who is already packing in a rifle, ammunition, optics, camping gear, and food, the addition of a compact HF communications kit is negligible in terms of weight and space, but the capability it adds is enormous.
“But the Ham Test Is Hard” — Cutting Through the Excuses
What the Technician License Exam Actually Requires
This is the part where the excuses need to die, because the number one reason preppers and hunters give for not getting a ham license is some variation of “I heard the test is really hard” or “I’m not an electronics guy” or “I don’t have time to study for some big exam.” Every single one of these objections is based on a misunderstanding of what the Technician exam actually involves, and once you see the reality, the excuses evaporate completely. The Technician class amateur radio exam consists of 35 multiple-choice questions drawn from a publicly available pool of roughly 400 questions. You need to get 26 correct to pass — that is 74 percent. The question pool is not secret. It is not hidden behind a paywall. It is published openly by the National Conference of Volunteer Examiner Coordinators and is available for free on multiple websites, most notably HamStudy.org. Every single question that could appear on your exam, along with every possible answer choice and the correct answer clearly identified, is right there for you to study. This is not like a college final where the professor might throw curveballs. This is a fixed pool of known questions with known answers, and your only job is to familiarize yourself with enough of them to get 26 out of 35 right on test day.
The content of the Technician exam covers basic radio theory, FCC regulations, operating procedures, electrical safety, and some elementary antenna concepts. It is not asking you to design a transceiver from scratch. It is not asking you to calculate complex impedance matching networks. It is not asking you to understand advanced calculus or electromagnetic field theory. It is asking you things like what frequency range the two-meter band covers, what the maximum power output for a Technician licensee is on certain bands, what type of emission is FM voice, what you should do if you hear a distress call on the air, and what the purpose of a repeater offset is. If you have ever read an owner’s manual for a piece of electronics, if you have ever studied for a hunter safety course, if you have ever taken a written driving test, you have the intellectual capacity to pass the Technician exam. The subject matter is not difficult. It is simply unfamiliar to most people, and unfamiliar is not the same as hard. Unfamiliar just means you need to spend some time with the material, and the amount of time required is shockingly small.
Free Study Resources and the Real Time Investment to Get Licensed
The data on this is clear and consistent across the amateur radio community. The average person who puts in focused study time passes the Technician exam in one to three weeks of casual preparation. Not months. Not semesters. Weeks. Many people pass it in under a week. The most commonly recommended study method is simply going to HamStudy.org, creating a free account, and working through the question pool using their adaptive study algorithm, which focuses your study time on the questions you are getting wrong and moves past the ones you already know. Fifteen to thirty minutes a day for ten to fourteen days is enough for most people to walk into the exam session and pass comfortably. If you prefer a more structured approach, the ARRL publishes the “Ham Radio License Manual,” which covers the entire Technician question pool with explanations and context for about $30. There are also multiple free YouTube channels that walk through the entire Technician question pool in video format — Dave Casler’s channel and Ham Radio Crash Course are two of the most popular and well-reviewed resources in the community. The point is that the resources are abundant, they are free or cheap, and they are specifically designed to get you from zero knowledge to a passing score in the shortest reasonable time.
Now consider the time and effort that the typical prepper or hunter already invests in other skills and gear. How many hours have you spent at the range working on marksmanship fundamentals? How many hours researching the best optic for your rifle, the best broadhead for your bow, the best water filter for your pack? How many hours watching gear review videos, reading forum threads about ballistic coefficients, or debating the merits of .308 versus 6.5 Creedmoor? Nobody in the prepper or hunting community blinks at spending 20 hours learning to reload ammunition or 40 hours scouting a new hunting unit before the season opens. But those same people will claim they do not have time to spend 10 to 15 hours studying for a test that unlocks a communications capability exponentially more powerful than anything they currently have. That is not a time problem. That is a priorities problem. And the sooner you recognize that communications is not a secondary concern but a primary survival skill on par with marksmanship, first aid, and navigation, the sooner you will carve out those 15 hours and get it done. The General class exam, which unlocks full HF privileges and is where the real long-range capability lives, is the same format — 35 questions from a public pool, 26 to pass. Most Technicians who decide to upgrade pass the General within a few weeks to a couple of months of additional study. Some people pass both exams on the same day at the same exam session, going from zero to General in one sitting. It is absolutely achievable for anyone with average intelligence and a willingness to put in the work.
The Gear Reality — What a Practical Ham Radio Setup Costs for Preppers and Hunters
Entry-Level HT and Mobile Rig Options That Will Not Break the Bank
The second most common excuse, right behind “the test is hard,” is “ham radio equipment is too expensive.” This objection might have had some validity 20 years ago when a decent HF transceiver cost $2,000 and a quality handheld was $300 or more, but the current market has completely demolished this argument. The entry-level price point for a functional amateur VHF/UHF handheld transceiver is genuinely lower than what most hunters spend on a single box of premium rifle ammunition. The Baofeng UV-5R, which is the most widely sold amateur radio handheld in the world, can be purchased for approximately $25 to $30. Now, the Baofeng is a controversial radio in the ham community — it has well-documented issues with spurious emissions, its receiver front end is easily overloaded in RF-dense environments, and its build quality is not going to win any awards. But it works. It transmits and receives on the two-meter and 70-centimeter bands, it can access repeaters, it can be programmed for APRS with an external TNC, and it has put more new operators on the air than any other radio in history. If you want something meaningfully better without spending much more, the Yaesu FT-65R runs about $80 to $90 and offers superior receiver performance, better build quality, and a more intuitive interface. The Yaesu FT-60R, a workhorse that has been in production for years and has a devoted following, typically sells for around $150 to $170 and is widely regarded as one of the most reliable dual-band handhelds ever made. Any of these radios, paired with a decent aftermarket antenna like a Nagoya NA-771, will put you on the air on VHF and UHF with solid performance for well under $200 total investment.
For mobile use — mounted in a truck, a UTV, or at a base camp — the options are equally affordable. The Yaesu FT-2980R is a dedicated two-meter mobile radio that puts out 80 watts and costs around $160 to $180. The Yaesu FT-8900R is a quad-band mobile that covers 10 meters, 6 meters, 2 meters, and 70 centimeters, giving you a taste of HF capability alongside full VHF/UHF coverage, for approximately $350 to $400. These radios, powered by a vehicle battery or a portable deep-cycle battery with a solar panel for recharging, give you a base station capability that can reach repeaters 50 to 100 miles away from a good location and provide reliable simplex communication over significantly greater distances than any GMRS radio can achieve in the same conditions. The total investment for a truck-mounted amateur mobile setup — radio, antenna, mount, coax cable, power cable — is typically $250 to $500 depending on the radio you choose. Compare that to what the average hunter spends on a single rifle scope, a single set of quality binoculars, or a single high-end sleeping bag, and the cost objection becomes laughable. You are not being asked to mortgage your house. You are being asked to redirect the equivalent of one moderately priced piece of gear toward a capability that could literally save your life or the lives of people you care about.
Field-Portable HF Setups for True Off-Grid Communications
The real game-changer for both preppers and hunters is portable HF, and this is where amateur radio enters a category that no other personal communications service can compete with at any price. A field-portable HF setup means you can establish communications over hundreds or thousands of miles from literally anywhere on the planet with no infrastructure, no subscriptions, no cell towers, no satellites, and no internet. You need a radio, an antenna, a power source, and the knowledge to use them. That is it. Five years ago, a portable HF rig that was truly field-worthy cost $800 to $1,500 for the radio alone, and it weighed ten pounds or more. Today, the market has changed dramatically. The Xiegu G90 is a 20-watt HF transceiver with a built-in antenna tuner that covers all HF bands from 160 through 10 meters, weighs about three pounds, and sells for approximately $450 to $500. It is not perfect — the receiver is adequate rather than exceptional, and the menu system takes some getting used to — but it is a fully functional HF transceiver that fits in a small daypack and can establish coast-to-coast communication on a good day with the right antenna and propagation conditions. The Yaesu FT-891 is a step up in performance, offering 100 watts of output power with a superb receiver, and it sells for around $650 to $700 with a weight of about five pounds. For the QRP (low power) enthusiast who wants the absolute lightest and most packable option, the tr-USDX is a multi-band QRP transceiver that costs under $100 in kit form, puts out about five watts, and weighs under a pound. Five watts sounds absurdly low until you remember that JS8Call and FT8 can decode signals far below the noise floor, which means five watts into a decent antenna on 40 meters can reach stations over a thousand miles away using digital modes.
The antenna is the other critical component, and for field use, simple wire antennas are king. An end-fed half-wave antenna for 40 meters is roughly 66 feet of wire with a small matching transformer, weighs a few ounces, and can be deployed by throwing one end over a tree branch and staking the other end to the ground. Total cost for a commercial EFHW antenna is $60 to $120, or you can build one yourself for under $20 in parts. A linked dipole cut for multiple bands can be made from speaker wire and a few connectors for even less. Power in the field comes from small lithium iron phosphate batteries — a Bioenno 4.5Ah LiFePO4 battery weighs about a pound, costs around $60 to $70, and will power a 20-watt HF radio for several hours of operating. Add a small folding solar panel for $30 to $50 and you have indefinite power in the field. The complete package — a Xiegu G90, an EFHW antenna, a LiFePO4 battery, a solar panel, coax, and accessories — comes in under $700 total and weighs under eight pounds. That is a fully self-contained, infrastructure-independent communications station that fits in a single stuff sack, can be deployed anywhere in less than ten minutes, and can reach across continents. Show me a GMRS setup that can do anything even remotely close to that, at any price, and I will concede the argument. You cannot, because it does not exist.
Building a Comms Plan That Actually Survives When Everything Else Fails
Integrating Ham Radio Into Your Preparedness and Hunting Communications Strategy
Having the license and having the gear are necessary steps, but they are not sufficient by themselves. A radio sitting in a box is not a communications plan any more than a rifle sitting in a safe is a home defense plan. The piece that separates people who are genuinely communications-capable from people who merely own radios is the plan itself — a structured, layered, practiced approach to communications that accounts for multiple failure modes and provides fallback options at every level. Building this plan is not complicated, but it requires deliberate thought and a willingness to actually use your equipment before you need it in an emergency. The foundational principle of a solid comms plan is layering, and amateur radio gives you the ability to build layers that GMRS simply cannot provide.
The first layer is local communications — talking to people within your immediate area, your family, your hunting party, your neighborhood group. This is where VHF and UHF simplex lives. You establish predetermined simplex frequencies on the two-meter and 70-centimeter bands that your group monitors, you program them into everyone’s radios, and you practice using them in the actual terrain where you plan to operate. This is critical and it is the step that most people skip. Programming a frequency into a radio at your kitchen table does not tell you whether that frequency will actually work in the canyon where you hunt elk or the valley where your retreat property is located. You need to go to those locations, key up, and find out. Test multiple frequencies. Test from multiple positions. Figure out which hilltops give you the best coverage, which drainages are dead zones, and where you need to reposition to establish a link. Document all of this in a written comms plan that every member of your group has a copy of — not stored on a phone that might be dead, but printed on paper or laminated on a card that lives in a pack or a pocket. Include primary and alternate frequencies, scheduled check-in times, and a procedure for what to do if a check-in is missed. This is basic stuff, but it is the basic stuff that saves lives, and it is the basic stuff that almost nobody actually does.
The second layer is regional communications — reaching beyond your immediate area to access repeaters, coordinate with other groups, or contact emergency services. This is where the amateur repeater network becomes your backbone. Before you need it, identify every amateur repeater within range of your operating locations. The RepeaterBook website and app is the definitive resource for this, listing thousands of repeaters across North America with their frequencies, offsets, PL tones, and operational status. Program the relevant repeaters into your radios and test them. Find out which ones you can hit from your home, your retreat property, your hunting camp, and your travel routes. Identify which repeaters have emergency power backup — many repeater listings on RepeaterBook include this information, and you can also contact the sponsoring club directly to ask. Repeaters with solar, battery, and generator backup are your priority assets because they are the ones most likely to survive a grid-down event beyond the first 24 to 48 hours. Build a repeater map for your area of operations and include it in your written comms plan. Know the input and output frequencies from memory for your top three or four repeaters so that if your radio’s programming is lost or you are operating a backup radio that has not been programmed, you can manually enter the frequencies and get on the air.
The third layer is long-range, infrastructure-independent communications — and this is where HF and digital modes come in, and where amateur radio completely separates itself from every other option available to individuals. With a General class license and an HF radio, you can establish communication over hundreds or thousands of miles using nothing but your own equipment and the ionosphere. Your comms plan should include predetermined HF frequencies and schedules for your group — for example, “Every day at 0800 and 1800 local time, monitor 7.185 MHz LSB for voice check-ins” or “Send Winlink messages every evening via the nearest RMS gateway on 40 meters.” These schedules and frequencies need to be agreed upon in advance, documented in your written plan, and practiced regularly so that when the day comes that you actually need them, the process is second nature rather than a frantic scramble through a manual. For hunting trips, the plan might look like this: your hunting partner and you carry two-meter handhelds for local communication in the field, you have a mobile VHF radio at base camp for repeater access, and you carry a portable HF rig that you deploy each evening to send a Winlink check-in email to your family confirming your location, status, and plans for the next day. If something goes wrong and you cannot make your scheduled check-in, your family knows to wait a predetermined grace period and then initiate contact with local search and rescue. That is a plan. That is layered. That is resilient. And it is only possible because amateur radio gives you the tools to operate at every layer — local, regional, and long-range — with and without infrastructure.
Training, Nets, and Practice — The Part Most Preppers Skip
There is a disease in the prepper community that is as widespread as it is dangerous, and it goes like this: buy the gear, put it in a bag, label the bag, put the bag on a shelf, and feel prepared. It happens with medical kits that never get opened until there is an actual bleed. It happens with water filters that have never been flushed and primed. It happens with firearms that get fired once at the range and then sit in a safe for three years. And it absolutely happens with radios. The number of preppers who own amateur radio equipment — sometimes very expensive equipment — but have never once transmitted on it, never participated in a net, never tested their antenna system, and never actually made a contact beyond their own front yard is staggering. This is not preparedness. This is collecting. And when the moment arrives that you actually need to use that radio to call for help, coordinate an evacuation, or relay critical information, your lack of practice will manifest as fumbling with menus, transmitting on the wrong frequency, not knowing how to set a repeater offset, or being unable to make your HF antenna load properly. These are not hypothetical failures. These are the exact failures that volunteer examiner coordinators and ARES emergency coordinators report seeing over and over again during exercises and real-world activations.
The fix is simple and it is free: get on the air and practice. The amateur radio community has a long-established tradition of nets — scheduled, on-air gatherings where operators check in, practice their communication procedures, and exchange information. There are local VHF nets, regional HF nets, digital mode nets, emergency preparedness nets, and specialty nets for virtually every interest within the hobby. Finding a net in your area is as easy as checking your local repeater’s published schedule or searching online for net directories. Checking into a net regularly — even just once a week for ten minutes — builds the operating skills and confidence that will make you effective when it actually matters. Beyond nets, participate in exercises. ARES groups across the country conduct regular Simulated Emergency Tests (SETs) and Field Day operations where operators practice setting up portable stations, establishing communications under simulated emergency conditions, and passing formal message traffic. These exercises are open to all licensed amateurs, they are well-organized, and they provide exactly the kind of realistic, hands-on training that turns a radio owner into a radio operator. The difference between those two things is enormous, and it is a difference that only practice can create.
For hunters specifically, the best training is simply using your radio equipment during actual hunts and backcountry trips. Bring your two-meter handheld on every hunt and use it. Try to hit repeaters from different locations. Note which spots work and which are dead zones. If you have an HF rig, take it on a camping trip and set it up. Make contacts. Send a Winlink message. Run APRS and watch your track appear on the map. Identify the problems — maybe your antenna matching is off, maybe your battery does not last as long as you expected, maybe your coax connector corroded from the rain — and solve them now, in a low-stakes environment, rather than discovering them when you are injured and alone in a drainage with no cell service and fading daylight. Every hour you spend operating your radio in the field is worth ten hours of reading about radio theory in your living room. The knowledge that comes from actually keying up, hearing your signal get into a repeater, making an HF contact on a wire antenna strung between two pines, or successfully sending an email through Winlink from a ridgetop with no cell coverage — that knowledge sticks. It becomes muscle memory. And it transforms you from someone who owns a radio into someone who can actually communicate when communication is the only thing standing between you and a very bad outcome.
The Final Word — Get Your License
Let me bring this full circle with complete honesty and no sugar coating. GMRS is not a bad service. It is a limited service, and it fills a limited role. For short-range family communications on a road trip, at a campground, or between a house and an outbuilding, GMRS is perfectly fine. Nobody should feel bad about owning and using GMRS radios for those purposes. But if you are a prepper who takes emergency preparedness seriously — who has invested real time, real money, and real thought into being ready for scenarios where normal infrastructure fails — then relying on GMRS as your primary or sole communications solution is an indefensible gap in your preparedness posture. It is the equivalent of having a comprehensive first aid kit but no training in how to use a tourniquet. The gear exists, but the capability does not, because the gear is not matched to the severity of the scenarios you are preparing for.
If you are a hunter who ventures into backcountry terrain where cell service does not exist and the nearest help is hours or days away, then carrying only a GMRS radio is an act of unjustified optimism. You are betting your safety on a radio service that cannot cross a ridgeline, cannot reach beyond a few miles in rough terrain, cannot provide GPS tracking, cannot send messages to the outside world, and cannot adapt to the specific propagation challenges of your environment. You deserve better tools than that, and those tools are available to you right now for a modest investment of time and money.
The Technician license exam is 35 questions from a public pool. You can study for free online and pass it in under two weeks. The exam fee is typically $15 or less depending on your local volunteer examiner team, and some teams charge nothing at all. The equipment to get started — a capable dual-band handheld — costs less than a decent knife. Upgrading to General, which unlocks the full power of HF and gives you infrastructure-independent global communications, requires one additional exam of the same format and difficulty. The total investment to go from zero to General class, fully equipped with a portable HF station, is less than what most hunters spend on a single guided hunt or what most preppers spend on a single case of freeze-dried meals. The return on that investment — the ability to communicate reliably in any scenario, from any location, under any conditions, with no dependence on any infrastructure you do not control — is without parallel in the world of personal communications.
Stop telling yourself the test is too hard. Stop telling yourself the equipment is too expensive. Stop telling yourself you will get around to it someday. The knowledge gap is real, but it is narrow. The capability gap between GMRS and amateur radio is real, and it is massive. Close the first gap, and you eliminate the second one permanently. Find an exam session in your area — the ARRL exam session search tool and HamStudy.org both have session finders — and go pass your Technician exam. Then get on the air. Then study for your General. Then build your comms plan, test your equipment in the field, and start checking into nets. Do the work. Because when the cell towers are dark, the power grid is down, the internet is gone, and your GMRS repeater is a silent box on a hilltop with a dead battery, the only voice that is going to cut through the noise and reach the people who need to hear it is the one transmitting on amateur radio frequencies with the knowledge, the license, and the capability to make the contact. Be that voice.
Call to Action
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D. Bryan King
Sources
- FCC — General Mobile Radio Service (GMRS) Overview
- FCC — Amateur Radio Service
- ARRL — What Is Ham Radio?
- ARRL — Amateur Radio Emergency Service (ARES)
- ARRL — NVIS Propagation Overview
- HamStudy.org — Free Exam Study Resource
- APRS.fi — Automatic Packet Reporting System Live Map
- JS8Call — Keyboard-to-Keyboard HF Messaging
- Winlink — Global Radio Email System
- NWS — Skywarn Storm Spotter Program
- GAO Report GAO-18-472 — Puerto Rico Hurricanes: Status of FEMA Funding, Oversight, and Recovery Challenges
- FEMA — Amateur Radio Operators Provided Critical Communications During Hurricanes
- QRZ.com — Callsign Lookup and Amateur Radio Community
- ARRL — Getting Your Amateur Radio License
- Signal Identification Wiki — Digital Mode Reference
Disclaimer:
The views and opinions expressed in this post are solely those of the author. The information provided is based on personal research, experience, and understanding of the subject matter at the time of writing. Readers should consult relevant experts or authorities for specific guidance related to their unique situations.
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