Our Amateur Radio and the Maker Community post defined our stance that the future of ham radio is in experimentation and learning. This post builds upon that cornerstone article by outlining why you should even bother getting an amateur radio license. I won’t make points around the ability to talk around the world or independence from infrastructure that are often touted as benefits of ham radio. Instead, I will highlight why as a hardware designer and a software developer having your amateur radio license is a ticket to designing more interesting, useful, and complex projects.

The Federal Communications Commission provided US citizens with an amazing opportunity to experiment with and develop innovative technology when creating Part 97. You should take advantage of this opportunity. Let’s take a closer look at it!

Part 97, Part 15, and Part 18 (ISM)

We’ve seen these terms thrown around with little explanation. Often, they are taken at face value when you come across a transceiver on Adafruit or Sparkfun. In-reality there are very specific reasons a radio may be one or the other and in most-cases not requiring a license is preferred by manufacturers. That’s why Adafruit and Sparkfun do not focus on selling ham radio transceivers. We on the other-hand tailor to radio amateurs. FaradayRF specifies right on our Starter Pack that you must be a licensed radio amateur to use Faraday.

Licensed Versus Unlicensed Spectrum Use

Before we dive into the regulations lets take a moment to talk about the use-cases of each type of radio. We should be careful to directly compare radios such as Faraday which require an individual license against radios such as the Sparkfun RFM69 Breakout as they are aimed at very different use-cases.

Unlicensed radios operating under Part 15 let you do essentially whatever you want as long as you don’t change the manufactured device. There is no requirement to identify who you are and you can encrypt all your communications. Broadcasting is even allowed. Projects looking to connect to WiFi or Cellular networks will absolutely want to be encrypted so they should use these radios. However, as a hardware designer and software developer you’re not allowed to modify the radio or run higher power. Additionally, you’re at the whim of politics and interpretation as seen in the FCC firmware lock-down saga which is still a problem but has been alleviated because some manufacturers are taking a small stand.

Licensed radios operating under Part 97 on the contrary allow you to modify the hardware, firmware, and software to your hearts content. Most operating modes on most bands even allow you to push out 1500W to the antenna (not including antenna gain!) which is honestly just crazy amounts of power. Since most amateur bands give radio amateurs primary or at least privileged use of RF spectrum other users have to accept if you interfere and radio amateurs can also legally challenge interference against unlicensed users if necessary. There are many cases where this power has been helpful and one of the most notable cases is the ARRL and Broadband over Power Lines clash.

While you cannot encrypt your communications the debate is out whether authentication is legal. Exploring authentication will prove to be a fun endeavor in the near future for ham radio. With the lack of encryption the amateur radio community has a completely different feel to it since they want to communicate with each other. Generally, you don’t want your neighbors on your WiFi router but with ham radio we actually want them to join in most of the time. This helps create a community of experimenters that I’m proud to have been a part of since 2004!

Being able to hack at your hardware, firmware, and software just because you passed the easiest amateur radio test to get your technician class ticket makes the effort worth it. Projects like Faraday encourage open communication, open experimentation, and active collaboration on projects that are higher power and longer range than most unlicensed offerings. Next we will explore the differences between the radio services but remember that your amateur radio license doesn’t stop you from using unlicensed radios. It gives you all the privileges aimed at experimentation which I’ve outlined and lasts a lifetime with simple renewals once every 10 years. It’s worth it.

ISM and Part 15 is the Same Thing Right?

No! This is a really easy mistake to make. The Part 18 Industrial, Scientific, and Medical (ISM) band radios are not allowed to be used for telecommunications. See §18.107(c) which defines ISM equipment as “Equipment or appliances designed to generate and use locally RF energy for industrial, scientific, medical, domestic or similar purposes, excluding applications in the field of telecommunication“. The ISM bands provide areas of RF spectrum where unlicensed transmissions can occur that are often dirty, broadband, and sporadic. If you’re going to have these types of transmitters emit RF and they generally only need to transmit then grouping them together makes sense.

FCC Part 15 addresses the telecommunications gap for unlicensed use. Part §15.1(a) classifies what types of devices fall under it “This part sets out the regulations under which an intentional, unintentional, or incidental radiator may be operated without an individual license“. The last part about operating without an individual license is the most important statement. If you do not assume the operator is technically skilled enough to understand proper operation then it’s up to the manufacture to make sure the electronics are compliant as marketed and shipped to the consumer. This makes sense due to the FCC having no ability to determine whether you’re skilled enough to operate legally as a general consumer.

Part 15 Radios Using the ISM Bands

Many wireless solutions for makers and experimenters often operate in the ISM bands. This falls under Part §15.247which defines operation on 902-928 MHz, 2400-2483.5 MHz, and 5725-5850 MHz. These bands are three really popular ISM bands with the latter two best known for IEEE 802.11 WiFi use. Even the CC430F6137 used in Faraday is aimed directly at operating under Part 15 on the 902-928 MHz ISM band, that’s why we chose it! There is also a very good reason for manufacturers using ISM bands for unlicensed communications under §15.247. Most Part 18 users who can file complaints against part §15.247 devices do not even attempt to receive in the ISM band. In other words, the lights are on but no one is home.

ISM use is generally used for one-way transmissions such as microwave ovens, medical heating therapy, and IC wafer manufacturing (creating plasma with RF). Most CFL lightbulbs are Part 18 due to the RF energy needed to excite the mercury vapor inside them! Therefore any Part §15.247 radio transmitting on these bands is extremely unlikely to cause any noticeable interference to an ISM device. Secondly, when you as an experimenter use these radios and modify them (however legal that actually is) it will be much more likely that any interference which results will go unnoticed.

So What About Amateur Radio?

The FCC Part 97 rules define what Amateur Radio is. Amateur radio is justified in §97.1 using five points, of which the fourth is our favorite “Expansion of the existing reservoir within the amateur radio service of trained operators, technicians, and electronics experts“. This right here is why we love amateur radio! One of the founding principles of the hobby was to spur innovation.

I will highlight why as a hardware designer and software developer having your amateur radio license is a ticket to design more interesting, useful, and complex projects

You need not look much further before finding §97.103 which clearly states “The station licensee is responsible for the proper operation of the station in accordance with the FCC Rules“. Unlike general consumers the FCC trusts you, a licensed radio amateur, as being capable of properly operating your station. In the more than 100 years of ham radio this expectation of trust and self-regulation has worked out far better than one would initially assume.

So far we’ve only showed you why earning the FCC’s trust is beneficial. Now we will show you what that trust gets you! That’s where §97.303 comes in. Faraday operates on the 33 cm ham band (902-928MHz) as a Part 97 device. More importantly §97.303(b) and §97.303(e) define how we as radio amateurs can use the 33 cm band.

(b) Amateur stations transmitting in the 70 cm band, the 33 cm band, the 23 cm band, the 9 cm band, the 5 cm band, the 3 cm band, or the 24.05-24.25 GHz segment must not cause harmful interference to, and must accept interference from, stations authorized by the United States Government in the radiolocation service.

(e) Amateur stations receiving in the 33 cm band, the 2400-2450 MHz segment, the 5.725-5.875 GHz segment, the 1.2 cm band, the 2.5 mm band, or the 244-246 GHz segment must accept interference from industrial, scientific, and medical (ISM) equipment.

As a maker interested in amateur radio these are profound opportunities. You are allowed to transmit unless you cause interference to the “United States Government in the radiolocation service” and you must receive interference from ISM band devices since we are secondary users of this band. As I stated earlier you are not allowed to interfere with ISM devices but since almost no ISM devices have receivers, interfering would prove very difficult to do in practice.

The requirement not to interfere with the United States Government sounds scary but KB9MWR has a great web-page talking about just what these uses are. In summary, you have little chance of actually being required to stop transmitting due to interfering with government radiolocation services. This leaves the requirement of accepting ISM interference as the only real downside to using the ISM band for ham applications. As long as you are OK with some extra RF noise the 33cm band is wide open for ham radio.

The ISM Bands are Junk!

So, ISM bands are largely relegated to “junk” use and radio amateurs must accept interference from ISM devices when using them. This doesn’t mean you have to stop using them when interfered with, it means you have no legal ability to complain about an ISM device bugging you. This is true for Part 15 devices as well and yet we use ISM bands for communications all the time with WiFi on 2.4 GHz and 5 GHz. Most garage door openers, wireless headphones, and baby monitors use ISM bands as well. For example, sometimes our microwaves cause WiFi to slow down but most of the time we never notice.

Amateurs have often denounced the 33 cm band (902-928MHz) as junk due to the noise heard on it. This however is antiquated advice. Digital transmissions are much less susceptible to observation of noise than analog transmissions. Using 33 cm for FM voice maybe be irritating but digital users may never notice the noise.

This is why Faraday is pushing the use of 33 cm for hams. Combined with the incredible privileges of a ham radio license, Faraday is set to be revolutionary for the 33 cm ham band. We want you to start experimenting, start learning, and start using amateur privileges on the 33 cm ham band.

Go Earn Your Amateur Radio License… Now!

We’ve convinced you that being a radio amateur is pretty badass. We know it is, too. As a designer or programmer you will find it easy to “earn your ticket” with a little study. The opportunities to work on interesting projects with increased functionality, range, and reliability are a few of many reasons an amateur radio license kicks-ass. Using your Part 97 license gives you the right to build more powerful, more complex, and more useful projects than possible using unlicensed radios.

To use Faraday or any other amateur radio transceiver on the 33 cm band you only need a Technician class license in the United States. This is the easiest license to get and requires no Morse Code skills. The AmateurRadio subreddit has an awesome wiki page on what you need to do to become licensed. Check it out, get your license, and push the boundaries of RF experimentation with us.

We are excited to see you get licensed! If we’ve convinced you to get your license please let us know. We’d also love to hear your thoughts on the benefits and drawbacks to using ISM, Part 15, and Part 97 devices here in the United States. Leave us your thoughts in a comment below!

We are simply conversing about published documentation regarding ISM, Part 15, and Part 97 regulations and are not lawyers! Do not take this article as legal advice.

The latest blog post by Sterling Coffey (N0SSC), Millennials Are Killing Ham Radio, dives into a topic we’ve brought up continually here at FaradayRF. That topic is the future of amateur radio. We’ve known Sterling for a long time and this post comes as no surprise to us. He’s an ardent supporter of FaradayRF and even gave an impromptu lightning talk about our project at the 2017 TAPR/DCC.

Being a millennial myself, I barely remember not having a computer in the house and when we did have a computer there was at least dial-up Internet to go with it. By the time I was in high school most of us had cell phones and in 2007 when I graduated high school the iPhone changed the world. To put it bluntly, mainstream ham radio has always been behind the curve of mainstream technology for as long as I can remember. Rather than being deterred, people such as Sterling, my brother Brent, and myself have taken on the optimistic view that we can reinvent amateur radio.

Here’s how…

Millennials are Savvy

Growing up with computers and the Internet makes us a bit naive about technology. If we think it can be done then we can probably figure out how do it. This is a great trait because no one can tell us it’s not possible. Just because it wasn’t possible before doesn’t meant I can’t do it now. We didn’t grow up designing computers from scratch. We grew up piecing graphics cards, hard drives, and motherboards together while figuring out how to boot Linux (all before Ubuntu!). That’s made us savvy with technology. Some of us can design computers, but a heck of a lot more can cobble them together and apply them to something interesting. That’s progress.

Millennials are Efficient

Building upon our savviness, I’d argue that millennials are efficient too. In fact, today’s fast-paced world means few have interest in becoming licensed to slow down and ragchew over HF. Love it or hate it that’s a strong trait I’ve observed. It’s trivial to contact almost anyone anywhere in the world if there is an Internet connection. It’s a hard sell to put ham radio in any other context beyond emergencies, contesting, and being something like sailing.

Using the resources available to us we can iterate quickly without reinventing the wheel. Building projects starts at proof of concept which involves wiring premade circuit boards together and applying some software glue. We know that building upon others work is faster. We grew up with open source and that’s changed our perception of what a project is. It’s efficient to take what works now and build something better. Some will enjoy building 40 meter CW transmitters but many more will find value in much more relevant technology applied to amateur radio. There are likely more millennials interested in working at the application layer than at the transistor layer of a radio.

Millennials are a Step Ahead

Readers of our blog as well as the massively popular Hackaday blog will note that open source electronic design software such as KiCad and manufacturers such as Oshpark give millennials a leg up versus prior generations. For less than $20 and two weeks of time one can order a four-layer circuit board that has good performance through 1GHz. This is insane compared to just 20 years ago!

The tools available to millennials allows them to experiment and iterate at speeds unseen before in amateur radio. This allowed projects such as FaradayRF and HackRF to quickly iterate hardware with minimal investment. Additionally, SMT components are the standard for most hobbyists these days. While 0402 components may be annoying, some of us are hand soldering 0201 components (dust) and 0603 or larger are a breeze. Hardware is getting much cheaper. Hardware is practical.

Millennials are not Patient

A blessing and curse of growing up as a millennial is that we’re not very patient. We went from dial-up Internet to broadband cable in a decade as kids. We went from no-frill cell-phones to having a smartphone that provided high speed Internet in our pockets in half a decade. Finally, we’ve seen smartphones nearly replace the need for desktop/laptop computers in another half a decade after that. Technology moves fast, and we expect that. Ham radio isn’t an exception to these forces. I’d call this progress and we need to keep up.

It’s our Time

The attitudes, savviness, and naive view of what couldn’t be done in the past can provide the driving force in ham radio. It could also drive its disappearance into irrelevance. Millennials are now in their 20’s and 30’s. Among us are the Steve and Woz’s of our generation building Apple or the Bill Gates starting Microsoft. Among us are the people ready to take what we’ve learned growing up and see the opportunity to build a better version of tomorrow. Millennials are poised to define a new paradigm for the hobby. I say we should welcome it.

What do you think about millennials driving the future of ham radio? We’d love to keep this discussion moving forward. It’s an exciting time to be a radio amateur. We’re on the cusp of becoming forever a retro activity or catapulting into an era of fast-paced advancement. Let us know what your thoughts are in the comments section below!

Metrology is the science of measurement. The International System of Units, also called SI, consists of standards which result from meticulous negotiations among international metrologists. The purpose of the International System of Units is to communicate quantitative information clearly across languages and cultures.

This check-list summarizes the most important elements of those standards. For more detail, you may wish to download the PDF document NIST Special Publication 811, 2008 Edition, by Ambler Thompson and Barry N. Taylor: Guide for the Use of the International System of Units (SI). A relevant Wikipedia article is also useful. The Bureau International des Poids et Mesures (BIPM) also publishes useful information in French and English.

Here is a simple checklist to help you use SI correctly:

• Except for degrees Celsius, SI units like microfarads and millivolts are always written in lower case and are almost always pluralized. (See below for exceptions to the usual pluralizing standard.) Because of their phonetics, some SI units like megahertz are written the same in singular and plural.
• SI symbols like kHz and µV are written in lower case or UPPER CASE Latin or Greek characters or in combinations. SI symbols are the most universal parts of SI, and are never pluralized.
• Be careful with UPPER and lower case: UPPER CASE M is the SI symbol for the mega- prefix; lower case m is the symbol for meters or metres as well as the milli- prefix; lower case Greek µ is the symbol for the micro- prefix. With the advent of computer word processors, using u as a substitute for µ is an obsolete practice. Lower-case italic m represents mass. UPPER CASE K is the SI symbol for thermodynamic temperature in kelvins and lower case k is the SI symbol for the kilo- prefix. One should not be used in place of the other.
• With three exceptions, SI values and SI symbols are always separated with spaces and never with anything else. Those exceptions are the symbols for angular degrees, minutes and seconds. The 100 m dash and a 10 A fuse are correct expressions. It is also correct to write: The summit of 6190 m Denali in Alaska is located at 63°04’08.7”N 151°00’25.5”W.
• When used in an adjectival sense in English, SI values and spelled-out SI units are separated with hyphens and are not pluralized: the 100-meter dash and a 10-ampere fuse are correct expressions. When accompanying values of exactly 1 or -1, SI units are not pluralized.
• Abbreviations do not exist in SI. Instead of abbreviations like amps and secs, use SI symbols like A and s or fully spelled-out SI units like amperes and seconds. Note that the symbol for the time unit minutes is min, which is not an abbreviation, and therefore it is not pluralized and it is not followed by a period.
• Never use SI prefixes in isolation. Avoid using expressions like 10 kilos of flour or 5 K run; use 10 kilograms of flour or 10 kg of flour or 5-kilometer run or 5 km run instead.
• Except at the end of a sentence, an SI symbol is never followed by a dot or period. To avoid confusion, try not to end sentences with SI symbols if possible.
• Fractional SI values are decimalized and preceded with a zero or other integers: 0.529 µm or 0.529 micrometers.
  
• Since either a dot or a comma may be used in SI as a decimal marker, the comma should never be employed as a separator for long integers or long fractions. Segment values with five digits or more utilizing spaces or half spaces. Using a word-processor, create a half space by changing the font size of a regular space to about half the value of the rest of the text. The speed of light, whose symbol is italic c [see footnote 1] is 299 792 458 m/s or 299 792.458 km/s or 299.792 458 Mm/s when written in SI. The speed of light may also be written as 299 792,458 km/s or 299,792 458 Mm/s without any change in meaning.
• SI symbols should never include suffixes. Instead of 115 VAC, write AC 115 V or 115 volts alternating current in correct SI.
• Avoid orphaned values. Instead of 9-15 volts or 9-15 V, write 9 volts to 15 volts or 9 V to 15 V in SI.
• SI dates are rendered with numerals in descending order. The origin of what became the International System of Units began in Paris on 1875-05-20 with an international treaty. SI time is reckoned in the 24-hour system, often with the time zone specified: 1445 UTC or 0657 EST.
• SI standards have changed over time. Avoid obsolete expressions. The old degrees kelvin should be kelvins (symbol K). The obsolete mhos should be siemens (symbol S), which is followed by an s in both singular and plural unit forms. The old cubic centimeters unit is still commonly used in medicine, but milliliters or millilitres (symbol mL) [see footnote 2] should be used instead. The obsolete microns unit is now micrometers or micrometres (symbol µm). Multiple prefixes like µµ or micromicro- are no longer allowed in SI. Use the pico- unit prefix or the p- symbol prefix instead. An acceptable SI substitute for the obsolete parts per million (ppm), parts per billion (ppb) has not yet been developed. If international metrologists eventually agree on an SI unit and symbol for nominal-scale entities, then fractional prefixes combined with that unit or symbol will do a good job of carrying out that proportional function.

¹ Quantities to be measured and their symbols are written in italics: current and inductance are examples. Think of e=mc² and I=E/R.

² Although lower-case l may be used as a symbol for liters of litres, that character may be mistaken for the numeral 1, so most writers prefer the upper case L for that symbol.

Stories you’ll find in our December, 2017 issue:

The Beginning of Sports Broadcasting and Radio’s First Sportscasters
By John Schneider W9FGH

Despite its great advantage of immediacy, radio did not become a dominant news medium until the start of World War II. Throughout the 1920s and 30s, newspaper owners were successful in keeping the press news agencies from selling their services to broadcasters, and radio remained a secondary source for news. But, the reporting of sporting events was another story. Sports and radio were a made for each other like ball in glove, and the country’s broadcasters were quick to capitalize on that advantage from the industry’s earliest years. John charts the rise of sports on American radio.

The Brief and Colorful History of Private US Shortwave Giants
By Richard Fisher KI6SN

In AM radio’s ever-evolving place in broadcasting history, there was a time when U.S.-based AM stations took to the shortwaves, either as standalone broadcasters or as an extension of their AM broadcast band partners. While their popularity soared in the 1970s and ’80s, many have vanished as others carry on.

Powerhouse American shortwave stations, including WRNO, WNYW, WBCQ, KUSW and KNLS, profiled here, had (or have) a substantial worldwide following on the high frequencies. In this 21st Century, many are gone or have changed formats from, say, popular music and news to Christian oratory or other programming. Richard looks back at some of these stations.

Meter Matters: Modern vs. Vintage Meters in Radio Restoration
By Rich Post KB8TAD

What happens when you calibrate that Hickok tube tester at those 150 and 130 voltage specifications or the bias voltages ignoring the line that calls for that ancient 1000 ohms-per-volt meter and just use a digital meter like my very-expensive-when-new Fluke 87 or that bargain Harbor Freight CenTech P37772 instead? Well, the calibration for your Hickok will be off. Those modern meters have a specified sensitivity of 10 megohms. Rich warns that not all that will be off as he examines the use of various meters in vintage radio technology.

TSM Reviews: Yaesu FT-70DR
By Cory GB Sickles WA3UVV

When an item is released that offers breakthrough technology or more features and benefits than previous models, the price is typically higher. When the price of an item is higher, many tend to hesitate in buying it. Further, economy of scale eventually kicks in, allowing a manufacturer to lower prices a bit, or produce and release additional models with many of the features of the premier version. The FT-70DR (FT-70DE in Europe) is the latest dual-band portable and takes its place in the market with a substantial entry-level feature set, as well as being the most inexpensive portable produced by the “traditional” amateur radio manufacturers—all for a street price of just under $200.

Scanning America
By Dan Veeneman
Interoperability Update; Orange County, Virginia

Federal Wavelengths
By Chris Parris
Urban Area Security Initiative (UASI)

Milcom
By Larry Van Horn N5FPW
Introduction to Military Monitoring: VHF Low Band—the Forgotten Military Band

Utility Planet
By Hugh Stegman NV6H
North Korea Resumes HF “Numbers” Broadcasts

Shortwave Utility Logs
Compiled by Hugh Stegman and Mike Chace-Ortiz

VHF and Above
By Joe Lynch N6CL
The Geminids and Ursids Meteor Showers

Digitally Speaking
Cory GB Sickles WA3UVV
System Fusion II

Amateur Radio Insights
By Kirk Kleinschmidt NT0Z
A Vertical in Hospice!

Radio 101
By Ken Reitz KS4ZR
AM Band DXing Circa 1964 and Now

Radio Propagation
By Tomas Hood NW7US
Heliophysics Research Reveals More About Substorm Mysteries

World of Shortwave Listening
By Rob Wagner VK3BVW
Making Shortwave Audio More Listenable

The Shortwave Listener
By Fred Waterer
2017 SW Review and New Programming

Amateur Radio Satellites
By Keith Baker KB1SF/VA3KSF
A Wealth of New Amateur Radio Satellites

The Longwave Zone
By Kevin O’Hern Carey WB2QMY
Primetime Arrives!

Adventures is Radio Restoration
By Rich Post KB8TAD
What’s an “Acoustic Labyrinth?” The Stromberg Carlson 240M

The Spectrum Monitor is available in PDF format which can be read on any desktop, laptop, iPad®, Kindle® Fire, or other device capable of opening a PDF file. Annual subscription is $24. Individual monthly issues are available for $3 each.

Some HF digital modes were designed for long-distance (DX) radio-wave propagation via the ionosphere. One such keyboard-to-keyboard digital mode is Olivia.

Friday evening, 8 December 2017, at 0200 UTC {9-DEC}, Larry, N7ZDR, called an Olivia-mode 80-Meter digital roundtable net. The following video is a snapshot of about nine minutes of on-air net operations as received at my location in Omaha, Nebraska.  My antenna is a wire run from an SEA marine autotuner mounted under the three-story-high roof’s eaves.  I live in a high-RF environment within two miles of eight high-powered broadcast antenna facilities–TV, FM, AM–as well as business and public-service transmitters.   All that RF desensitizes my receiver.  The noise floor is also affected by industrial-level man-made RF noise.

No, Olivia is not lightening-fast keyboard-to-keyboard chatting, but it can get the job done. This following video shows some real-world operation in which the very weakest signals did not decode well. However, even with the 80-Meter band (center frequency is 3585 kHz) really difficult to work with, it did well in terms of what was available for the Ham Radio Deluxe DM780 software to decode.

Example QSO in Olivia Video:

In 2005, SP9VRC, Pawel Jalocha, released to the world a mode that he developed starting in 2003 to overcome difficult radio signal propagation conditions on the shortwave (high-frequency, or HF) bands. By difficult, we are talking significant phase distortions and low signal-to-noise ratios (SNR) plus multipath propagation effects. The Olivia-modulated radio signals are decoded even when it is ten to fourteen dB below the noise floor. That means that Olivia is decoded when the amplitude of the noise is slightly over three times that of the digital signal!

Olivia decodes well under other conditions that are a complex mix of atmospheric noise, signal fading (QSB), interference (QRM), polar flutter caused by a radio signal traversing a polar path. Olivia is even capable when the signal is affected by auroral conditions (including the Sporadic-E Auroral Mode, where signals are refracted off of the highly-energized E-region in which the Aurora is active).

Currently, the only other digital modes that match or exceed Olivia in their sensitivity are some of the modes designed by Joe Taylor as implemented in the WSJT programs, including FT8, JT65A, and JT65-HF–each of which are certainly limited in usage and definitely not able to provide true conversation capabilities.  Olivia is useful for emergency communications, unlike JT65A or the newly popular FT8. One other mode is better than Olivia for keyboard-to-keyboard comms under difficult conditions: MT63. Yet, Olivia is a good compromise that delivers a lot.

Join us — not just on the HF waterfall, but by joining our email-based group at:

–> https://Groups.Io/g/olivia

or, on Facebook at:

–> https://www.facebook.com/groups/olivia.hf

Thanks for spreading the Olivia love!  See you on the waterfall.

Addendum: 

Current CENTER Frequencies With 8/250 (eight tones, 250-Hz bandwidth): 

1.8269 MHz
3.5729 MHz
7.0729 MHz
10.1429 MHz
14.0729 MHz
18.1029 MHz
21.0729 MHz
24.9229 MHz
28.1229 MHz

See the pattern?

The current suggested CENTER frequency with 16/1000 or 32/1000 on 20 meters is 14.1059.

(Why the xxx…9 frequencies? Experts say that ending in a non-zero odd number is easier to remember!)

Q: What’s a ‘CENTER’ Frequency? Is That Where I Set My Radio’s Dial?

For those new to waterfalls: the CENTER frequency is the CENTER of the cursor shown by common software. The cursor is what you use to set the transceiver’s frequency on the waterfall. If your software’s waterfall shows the frequency, then you simply place the cursor so that its center is right on the center frequency listed, above. If your software is set to show OFFSET, then you might, for example, set your radio’s dial frequency to 14.0714, and place the center of your waterfall cursor to 1500 (1500 Hz). That would translate to the 14.0729 CENTER frequency.

The standard Olivia formats (shown as the number of tones/bandwidth in Hz) are 8/250, 8/500, 16/500, 8/1000, 16/1000, and 32/1000. Some even use 16/2000 for series emergency communication. The most commonly-used formats are 16/500, 8/500, and 8/250. However, the 32/1000 and 16/1000 configurations are popular in some areas of the world (Europe) and on certain bands.

These different choices in bandwidth and tone settings can cause some confusion and problems–so many formats and so many other digital modes can make it difficult to figure out which mode you are seeing and hearing. After getting used to the sound and look of Olivia in the waterfall, though, it becomes easier to identify the format when you encounter it. To aid in your detection of what mode is being used, there is a feature of many digital-mode software implementation suites: the RSID. The next video, below, is a demonstration on how to set the Reed-Solomon Identification (RSID) feature in Ham Radio Deluxe’s Digital Master 780 module (HRD DM780).

I encourage ALL operators, using any digital mode such as Olivia, to TURN ON the RSID feature as shown in this example. In Fldigi, the RSID is the TXID and RXID; make sure to Check (turn on) each, the TXID and RXID.

Please, make sure you are using the RSID (Reed Solomon Identification – RSID or TXID, RXID) option in your software. RSID transmits a short burst at the start of your transmission which identifies the mode you are using. When it does that, those amateur radio operators also using RSID while listening will be alerted by their software that you are transmitting in the specific mode (Olivia, hopefully), the settings (like 8/250), and where on the waterfall your transmission is located. This might be a popup window and/or text on the receive text panel. When the operator clicks on that, the software moves the waterfall cursor right on top of the signal and changes the mode in the software. This will help you make more contacts!

RSID Setting:

+ NOTE 1: The MixW software doesn’t have RSID features. Request it!

+ NOTE 2: A problem exists in the current paid version of HRD’s DM780: the DM780 RSID popup box that lists the frequency, mode, and configuration with a link to click, does not work. HRD support is aware of the problem. You can still use the textual version that shows up in the DECODED TEXT window, a feature of RSID that you can select in the HRD DM780 program settings. This setting ensures that the detected RSID details appear in the receive text area. If you click the RSID link that comes across the text area, DM780 will tune to the reported signal, and change to the correct settings.

Voluntary Olivia Channelization 

Since Olivia signals can be decoded even when received signals are extremely weak, (signal to noise ratio of -14db), signals strong enough to be decoded are sometimes below the noise floor and therefore impossible to search for manually. As a result, amateur radio operators have voluntarily decided upon channelization for this mode. This channelization allows even imperceptibly weak signals to be properly tuned for reception and decoding. By common convention amateur stations initiate contacts utilizing 8/250, 16/500, or 32/1000 configuration of the Olivia mode. After negotiating the initial exchange, sometimes one of the operators will suggest switching to other configurations to continue the conversation at more reliable settings, or faster when conditions allow. The following table lists the common center frequencies used in the amateur radio bands.

Olivia (CENTER) Frequencies (kHz) for Calling, Initiating QSOs

It is often best to get on standard calling frequencies with this mode because you can miss a lot of weak signals if you don’t. However, with Olivia activity on the rise AND all the other modes vying for space, a good deal of the time you can operate wherever you can find a clear spot–as close as you can to a standard calling frequency.

Note: some websites publish frequencies in this band, that are right on top of weak-signal JT65, JT9, and FT8 segments. DO NOT QRM weak-signal QSOs!

We (active Olivia community members) suggest 8/250 as the starting settings when calling CQ on the USB frequencies designated as ‘Calling Frequencies.’ A Calling Frequency is a center frequency on which you initially call, ‘CQ CQ CQ. . .’ and then, with the agreement of the answering operator, move to a new nearby frequency, changing the number of tones and bandwidth at your discretion. Even though 8/250 is slow, the CQ call is short. But, it is narrow, to allow room for other QSOs nearby. It is also one of the best possible Olivia configurations for weak-signal decoding.

– End of Addendum –

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