Everything Everywhere Daily: History, Science, Geography & More - Morse Code
Episode Date: June 21, 2022In 1838, an American portrait painter by the name of Samuel Morse developed a system whereby signals could be sent down an electrical wire. This system allowed for information to be sent almost ins...tantly over vast distances. However, sending pulses of electromagnetic energy down a wire isn’t in and of itself communication. So, he developed a system to encode these pulses in a way that was legible. Learn more about Morse Code, how it works and how it is actually still used today, on this episode of Everything Everywhere Daily. Subscribe to the podcast! https://link.chtbl.com/EverythingEverywhere?sid=ShowNotes Try Ka'Chava, your daily superblend for for health conscious people on-the-go https://www.kachava.com/Everywhere -------------------------------- Executive Producer: Darcy Adams Associate Producers: Peter Bennett & Thor Thomsen Become a supporter on Patreon: https://www.patreon.com/everythingeverywhere Update your podcast app at newpodcastapps.com Search Past Episodes at fathom.fm Discord Server: https://discord.gg/UkRUJFh Instagram: https://www.instagram.com/everythingeverywhere/ Twitter: https://twitter.com/everywheretrip Website: https://everything-everywhere.com/everything-everywhere-daily-podcast/ Everything Everywhere is an Airwave Media podcast." or "Everything Everywhere is part of the Airwave Media podcast network Please contact sales@advertisecast.com to advertise on Everything Everywhere. Learn more about your ad choices. Visit megaphone.fm/adchoices
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In 1838, an American portrait painter by the name of Samuel Morse developed a system whereby
signals could be sent down an electrical wire. This system allowed for information to be sent
almost instantly over vast distances. However, sending pulses of electromagnetic energy down a wire
isn't in and of itself communication. So he developed a system to encode these pulses in a way
that was legible. Learn more about Morse code, how it works and how it's actually still used today,
on this episode of Everything Everywhere Daily.
if your perceptions about the past were wrong.
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Time travel with us every week on the ThruLine podcast from NPR.
In some ways, the invention of the telegraph was far more profound than the communication
technologies which came after it.
Yes, the telephone and the internet could do much more and were better than what preceded them,
but the telegraph was basically competing with someone carrying a letter on a horse or a ship.
Future communication systems which came after were incremental improvements.
The telegraph, however, created an entire category of electronic communication.
The idea of an electronic device for communications actually dates back to the 18th century,
when concepts and early prototypes were built.
These systems were really impractical in that they used a separate wire for each letter
of the alphabet and could only transmit the distance of a single room. The discovery of the electromagnet
furthered things along as it allowed for a mechanical action to take place on the other end of an
electrical wire. The earliest telegraph systems were known as needle telegraphs. A needle telegraphs worked
by moving a needle to the right or the left depending on the current sent down the wire. The first needle
telegraphs tried to make the needle point to a letter of the alphabet, but eventually they settled on a code
where a letter would correspond to a series of needle movements.
For example, left left was the letter A, right right was the letter N.
Eventually, a five-needle system was developed where you didn't even need a code.
The needles would just point to the correct letter and then you didn't need a skilled operator.
But you did need five different wires, which proved difficult early on.
Many of the early systems developed in Britain were multi-wire systems, which was their weak point.
Each wire was a point of failure, and more wires equaled more cost.
There has been a running theme in this podcast when I talk about inventions.
Early versions or prototypes are often built or conceived decades or sometimes centuries before they come into regular use.
And the reason is that the first versions usually aren't practical or cost efficient to implement.
So too is the case with the telegraph.
The early multi-wire systems worked, but they weren't practical.
The first practical telegraph was developed by the American Samuel Morse and Alfred Vale.
Their system was a single wire system that didn't use any needles.
On the other end of the wire was a telegraph key which was part of an electrical circuit.
When the key was pressed on one end, it caused the key on the other end to depress making a sound.
I'm sure if you've ever seen a movie with a telegraph, you're familiar with the clickety sound of a telegraph key.
The very first version of the Morse system actually recorded the key coming down on a long, thin,
of paper similar to an old ticker tape, but that was eventually abandoned.
Morse demonstrated his system on May 24, 1844, on a connection between Washington, D.C. and
Baltimore, Maryland. Morse was in Washington, and Vale was in Baltimore, and Morse famously sent the
first message, which was, What hath God wrought? Morse's telegraph was very simple and much cheaper
than anything which came before it. As a result, it was rapidly adopted over the next several
decades as telegraph wires spread throughout the United States in Europe.
If you remember back to my episode on the transatlantic cable, the first telegraph message sent
across the Atlantic was in 1858, only 14 years after Morse's demonstration.
This episode, however, is not technically about the telegraph.
To send that famous message, Morse had to solve a problem.
How could he turn a bunch of clicking sounds into a comprehensible message?
A telegraph operator could only press down on a single key.
It turned out that the solution lay in the fact that you could vary the amount of time that the key was pressed down.
This led to different types of signals that could be sent based on time.
The shorter ones became known as dots and the longer ones became known as dashes.
The code that Morris developed was combining the short and long codes into letters of the alphabet.
So, for example, the letter A is dot-dash.
The letter B is dash dot dot dot.
If you learn this code, then you could both send and receive messages.
The early needle telegraph systems tried to achieve something easy to decipher at the cost of being
complex and expensive. The more system was cheaper and easier, but the trade-off was the need for a skilled
operator. The telegraph system actually evolved and was improved organically by these telegraph operators.
The early paper system that was abandoned was at the behest of operators who just found it easier to listen.
The operators developed abbreviations to make transmissions go faster,
many of which would seem shockingly familiar to anyone who's used text messaging in the 21st century.
The 19th century telegraph operators would have had no problem with LOL or OMG.
A train telegraph operator was a high-paying tech job, and there was a great demand for them.
It was the 19th century equivalent of a computer programmer.
Telegraph operators were able to actually tell who was on the other end of a wire based on how they transmitted their code.
There were unique styles and cadences that operators could identify after enough practice.
The code Morse developed was good, but there were problems with it that became evident early on.
For starters, it was designed around American English.
However, there are other languages that have letters beyond the 26 used in English.
Also, the first system developed by Morse had a few characters that were longer than a regular dash.
A dash was supposed to be twice the length of a dot, but the letter L, for example, was just four times as long as a dot, which could really get confusing.
Morse's original code became known as American Morse code.
In 1848, the German Friedrich Gerke developed a code based on Morse code for use in continental Europe.
Gurga got rid of the extended dashes and limited everything to nothing but dots and dashes to make it easy.
And he also created codes for European characters with diacritical marks such as an umlaut.
In 1865, a modified version of the Gurkha system, which was in and of itself a modification of the original Morse system,
was adopted into what was called International Morse Code.
That is the Morse Code that everyone in the world uses today.
Americans didn't adopt the International Code right away,
as the vast majority of messages were sent domestically,
and they didn't want to spend the time and effort to retrain their operators.
International Morse Code eventually became necessary
because telegraph lines were now being installed across borders,
and because of a new technology developed in the late 19th century, radio.
It turned out that Morse Code worked really well
with early radio. Instead of connecting a circuit, you could just broadcast the sounds directly.
Radio allowed for transmitting and receiving signals from ships and eventually airplanes.
As maritime radio increased, the International Radio Telegraphic Convention in 1906 created a
distress signal in Morse code that you're probably familiar with, SOS. SOS doesn't mean anything.
It's not an acronym. The letters were chosen simply because they're simple to remember in Morse code.
dot dot dot dash dash dash dot dot dot dot in 1904 a proposal was put forward to use cq d as a distress signal the reason for it was because cq was the word used by telegraph operators when starting a transmission the letters cq actually represent the french secu which is the first part of the word securitate so the d in cq d would be for distress cq is still the code used by amateur radio operators today when established
Ranghika connection. While CQD made sense in the logic of telegraph operators, it wasn't simple and
easy to remember, so SOS won out. The cruise ship R. Mest Slavonia was the first ship to send an SOS
signal on June 10, 1909. When the Titanic sank, the radio operator on board first sent a CQD
signal, and then on the advice of his assistant began alternating CQD and SOS. There were similar
systems developed for non-Latin alphabet languages. There is a Russian Morse Cove that maps
the Cyrillic alphabet, and there is a Waban code which maps to the Japanese Kana characters.
There's even a telegraph code for Chinese as well. The way they get around having so many
characters is that they assign each character a four-digit number. The numbers are transmitted
in regular Morse code. It sounds inefficient, but each Chinese character is efficient in how much
information a single character can convey, so it all sort of evens out. You just need to know
10 Morris Code characters, but then you need to have a sheet to decode the 10,000 possible combinations.
With the rise of telephones and voice radio, the demand for Morris Code operators plummeted.
However, it was still something that was taught to radio operators, even though it wasn't often
used for decades. The extremely simple nature of Morris Code means it's been adopted for uses
far beyond telegraph and radio. Major Alexei Castagli was a British prisoner of war in World War II.
During his captivity, he created a small wall hanging that he sewed by hand.
The Germans didn't think anything of it, but along the margins in Morse code, he stitched the phrases, God Save the King, and F. Hitler.
During the Vietnam War, American pilot Jeremiah Denton was shot down and captured.
On May 22, 1966, Denton and several other prisoners were taken to be interviewed by a team of Japanese reporters.
He was told to tell the reporters that he was being treated well.
However, with his eyes, he blinked out the letters,
T-O-R-T-U-R-E, torture.
Amateur radio, aka Ham radio operators,
used to need to learn Morse code to get a license,
and eventually it was only necessary
just to operate in high-frequency bands.
In amateur radio, Morse code is known as
Continuous Wave, or just C-W.
In the United States, the Morse Code test for amateur radio
was eliminated in 2006,
and the U.S. Air Force had its last Morse Code class
in 2015.
As Morse code fell out a favor, the number of people who knew Morse code dropped, rendering it even rarer.
But just like the Latin language, it never quite died.
There are still Morse code enthusiasts out there.
A very proficient coder can transmit 40 words a minute, and the very best can transmit up to 60.
You can still buy hand-built Morse code keys, and if you're interested in learning Morse code,
there are many free resources available online.
There are even free smartphone apps that will read and decode Morse code automatically,
even from an audio source.
And the Boy Scouts of America introduced an interpreter patch for Morse Code back in 2012.
The International Radio Union hosts the world high-speed telegraphy championships,
and countries in Eastern Europe always seem to do the best.
For the most part, Morse Code is a dead art reserve for hobbyists who keep it alive mostly out of nostalgia.
Nonetheless, it did play an important part in the history of electronic communications.
Everything Everywhere Daily is an Airwave Media podcast.
The executive producer is Darcy Adams.
The associate producers are Thor Thompson and Peter Bennett.
Today's review comes from listener M.B. Carpenter 81 over at Apple Podcasts in the United States.
They write, Gary never disappoints.
I look forward to this podcast every day.
Every episode is so well done.
I'm forever impressed how much information is packed into one single episode,
all the while keeping me intrigued every second.
Well done.
I also love Gary's travel photos on his Instagram account.
Thanks, M. B. Carpenter. I have to admit I haven't updated my Instagram as much lately as the podcast is now taking up all my time, and I haven't taken my camera out of my bag since the pandemic started.
However, if anyone is interested in seeing some of my photos from my years of traveling around the world, you can follow me at Instagram where my name is Everything Everywhere, all one word.
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