The symbol used in every email

©Mark Ollig

He invented the “@” sign we use to connect an email name with the computer host destination address.

Sending emails is such an everyday part of our lives; we don’t think much about it.

Every year, 74 trillion business and consumer emails are sent.

The name of the person we need to thank for today’s email is Raymond S. Tomlinson.

In 1971, Tomlinson was working with the DEC (Digital Equipment Corporation) KA10 PDP-10 computer program called TENEX, a time-sharing software program system operating on Digital PDP-10 computers.

Researching today’s column topic, I looked up the definition for “electronic mail” and was referenced back to the 1840s and inventor Samuel Morse’s use of his Morse Code – which technically was how mail messages were first sent or “keyed” by electronically coded means.

During the 1930s, messages were typed and received on teleprinter terminal machines electronically linked with each other over a shared network.

These machines were used mostly by governments, corporations, newspapers and the military.

The terminal’s message output was printed on paper. The early teleprinter looked a lot like a typewriter.

Telephone companies provided access to the Telex network (mostly via copper cable pairs) for the inter-connection of teleprinter machines. When I started in the telephone industry, we called the teleprinter connection a TWX (Teletype Wide-area eXchange) line.

I recall installing and maintaining TWX (pronounced “Twix”) lines for teletype terminals connected at the local police station, and the larger industries and businesses within the local telephone company serving area.

In the late 1960s, the US Defense Department began working on its own computer network called Advanced Research Projects Agency Network or ARPANET, which evolved into the internet.

Getting back to 1971, 30-year-old Ray S. Tomlinson began working on improving mail messages using a software program called SNDMSG, which his company used within their local network.

At this time, a user’s network mailbox was a simple message text file. User message files could only be sent and accessed over a shared mainframe/host computer network using a teletype machine.

Tomlinson considered the software program called CPYNET, which he realized could be used along with the SNDMSG program to transmit a user’s email or “message-files to other users on different computer networks.

Working with CPYNET software code protocols which transferred files through ARPANET, Mr. Tomlinson was able to incorporate it with the SNDMSG program code used for local inter-user mail.

He programmed these codes so the mail-file messages could determine the local computer host email from email destined to a remote computer host network.

Two host computers operating over separate networks were located in the room Tomlinson was working. The computers sat side-by-side on the same floor.

One computer was a DEC KA10 PDP-10, and the other was a smaller memory capacity model DEC.

Ray Tomlinson decided to use the “@” symbol to identify the terminating email address was “at” a different/remote computer host network; the email addressee was not on the same local computer network as the person originating the email.

By using the @ symbol, Tomlinson was able to use his programming code to connect the user name with the destination address and thus directed an email message to be sent out to a totally separate computer system over the ARPANET and reach its intended email address on the remote host computer.

The first email message was sent in late 1971 from the host computer over the ARPANET and to another computer located on another network.

Tomlinson says the first email message he sent likely contained the test word “QUERTYIOP” or similar. He said in later interviews that he hadn’t kept the original email.

Admittedly, that first e-mail message was historic. We do know the first email was typed on a Teletype KSR-33 terminal connected to one host computer which was successfully sent and received by another host computer’s Teletype KSR-33 on a different network.

"The invention of email came out of a personal desire for a more convenient and functional way to communicate,” Tomlinson said during his induction into the Internet Hall of Fame in 2012.  

“Basically, I was looking for a method that did not require the person to be there when the message was sent and enabled the receiver to read and answer communications at their convenience,” he added.

A photograph of where the first email message using the @ symbol sent between two different host computers over two different networks using Teletype KSR-33 terminals can be seen at https://bit.ly/1QXOhZU.

Tomlinson created the email addressing scheme user@host, which became the standard for email addresses and still is today.

He was a long-time employee of BBN (Bolt, Beranek, and Newman), which, at the end of 1968, won the 1968 US government contract to build the ARPANET, the forerunner of the internet.

Ray Samuel Tomlinson was born in Amsterdam, NY in 1941, and died March 5, 2016, in Lincoln, MA.

Photo created by me! :)

Web’s inventor expresses apprehension

©Mark Ollig

Tim Berners-Lee has been busy this week, attending events celebrating his 30-year-old invention – the World Wide Web.

Recently, he likened the web to a “public square, a library, a shop, a school, a doctor’s office, a bank, and so much more.”

“While the web has created opportunity, given marginalized groups a voice, and made our daily lives easier, it has also created an opportunity for scammers, giving a voice to those who spread hatred, and make all kinds of crime easier to commit,” said Berners-Lee.

He has concerns about what is happening to his web; here are three:

1. Deliberate, malicious intent, such as state-sponsored hacking and attacks, criminal behavior, and online harassment.

2. System design that creates perverse incentives where user value is sacrificed, such as ad-based revenue models that commercially reward clickbait and the viral spread of misinformation.

3. Unintended negative consequences of benevolent design, such as the outraged and polarized tone and quality of online discourse.

Berners-Lee acknowledges the web has created many new opportunities, including giving people a platform where their ideas and comments for improving society or a technical process can be easily heard by millions.

Unfortunately, the web has also become a venue for those who use it to spread negativity and online antipathy on a variety of subjects.

Many of us witness this negativity every day on social media.

We have seen online internet trolls who start arguments. They seem to be, for one reason or another, on the internet only to harass, distract, and upset people. They propagate their animosity with a constant barrage of negative messages. These trolls usually have pictureless profiles and anonymous or made-up names.

Most online trolls (many operate in wolf-like packs) seem to get some kind of kick out of triggering other online users’ emotions by posting negative replies and comments, or by continuously forcing their online agenda and getting a kick from the frustration in other people’s responses.

Whenever I come across these malicious online trolls in social networks, I immediately block them from my timeline so I don’t see them. I don’t play their game. It’s not worth getting stressed out, which is precisely the reaction they are seeking. Don’t give them the satisfaction; mostly, don’t let them stress you out.

Berners-Lee emphasized governments need to interpret laws and regulations for the digital age we are living in, which include protecting online individual user’s rights.

People who make up the “Web Champions” take action whenever the interests of the online public are threatened.

These Web Champions, according to Berners-Lee, can be civil servants and elected officials.

You and I can be Web Champions, too.

Examples of actions taken by Web Champions around the world include:

1. Holding governments responsible for ensuring a free and open internet/web.

2. Making sure the public has affordable access to the internet/web.

3. Preventing governments from censoring political and social content over the web.

4. Exposing government censorship of the web, and revealing the role it plays in threatening citizens’ access to it.

5. Alleviating the public’s anxiety about the web; education about its benefits is needed.

Security remains the web’s most significant threat; companies and individuals are always vulnerable to privacy and security risks.

Companies on the web need to test and update their safeguards used to protect the data entrusted to them by their customers. Secure online business practices always need to be encouraged.

Accountability needs to be enforced by online websites – whether governmental, public, or private – storing personal information.

Courses are available to minimize network security threats, along with countermeasures to protect against security hackers who attempt to infiltrate, intentionally breach security, and disrupt key online networks, such national banking systems, governmental agencies, and public utility companies. Popular social media networks, such as Facebook and Twitter, have had their security breached and websites rendered inaccessible.

The National Cybersecurity and Communications Integration Center provides information and many resources regarding cybersecurity at https://ics-cert.us-cert.gov.

“Citizens must hold companies and governments accountable for the commitments they make, and demand that both respect the web as a global community with citizens at its heart,” Berners-Lee said March 11.

Berners-Lee hopes everyone participating on the web will, in some way, contribute to its equality, opportunity, and creativity.

“The web is for everyone and, collectively, we hold the power to change it. It won’t be easy. But if we dream a little and work a lot, we can get the web we want,” stated Berners-Lee.

Let’s hope the web of the future can become a more civilized venue for holding open discussions and opinions without the social media online troll attacks, fear of data theft, or website disturbances caused by devious computer hackers.

The Web Foundation is working with governments, companies, and citizens in building a brand-new “Contract for the Web.” Learn more about this project at https://webfoundation.org.

Half of the world is online and using the web – the other half is still offline without web access.

Berners-Lee’s vision 30 years ago was to have a free and open web for everyone.

Hopefully, those around the world without internet/web access won’t have to wait 30 more years to join the World Wide Web.

(Image Royalties Right-To-Use fee paid)

Proposal for the web began 30 years ago

©Mark Ollig


March 12, 1989, a British computer scientist named Tim Berners-Lee presented a document proposal on how to share information within his organization.

Berners-Lee was working in Geneva, Switzerland at the European Organization for Nuclear Research; better known as CERN.

He wanted to make it easier to exchange data within the CERN organization.

The name of Berners-Lee’s document was “Information Management: A Proposal.”

Berners-Lee wrote a software program for allowing information contained within different types of computers to be distributed over a shared network among thousands of scientists and researchers working for CERN.

His solution: a distributed hypertext system.

To be fair, Ted Nelson coined the word hypertext in the early 1960s.

While writing about a “simple user interface” for use over a computer network, Nelson used the word hypertext in describing his Project Xanadu, which never became a working reality for him until 2014, with the release of OpenXanadu.

In the 1989 proposal, Berners-Lee described his experience with hypertext, “In 1980, I wrote a program for keeping track of software with which I was involved in the PS [Proton Synchrotron] control system, called Enquire. It allowed one to store snippets of information, and to link related pieces together in any way. To find information, one progressed via the links from one sheet to another.”

Berners-Lee diagramed a flowchart showing how users of the CERN network could distribute, access, and collaborate on documents within electronic files located on various data servers.

Electronic documents could be viewed and modified by a user, no matter which type of computer or operating system they used.

Berners-Lee wrote about a generic client “browser” software program which would allow a user of the CERN computer network to interact with the hypertext data servers.

While reading through his proposal, I smiled upon seeing an analogy between “the telephone book” and hypertext. Berners-Lee said both contained “links between people and sections, sections and groups, and people and floors of a building.”

The “people and floors of a building” sounds like he was describing a telephone extension directory used in large organizations having their own internal telephone system; such as a PBX (private branch exchange).

“Most systems available today use a single database. This is accessed by many users by using a distributed file system,” Berners-Lee wrote.

Granted, the database could store a lot of information; however, it was all in one place, he stated.

Berners-Lee would create protocols for a computer to link to and connect with different computer databases storing electronic documents on a shared network, no matter where they resided.

What Berners-Lee was proposing to his colleagues 30 years ago, was the foundation for today’s World Wide Web.

When you see “http” in your web browser, the “ht” stands for HyperText. The “tp” means Transport Protocol, thus the abbreviation: HTTP.

The “s” in https means it is a “secure” version of HTTP, and the communications between your web browser and website are encrypted for privacy.

Berners-Lee wrote the code used for the start of all web addresses; HyperText Transfer Protocol, the web’s programming language; HyperText Markup Language (HTML), and the first web browser; WorldWideWeb, on a NeXTcube workstation.

The NeXTcube was built by NeXT, Inc., which was owned by Apple Computer’s co-founder, Steve Jobs.

Nov. 12, 1990, he and colleague Robert Cailiau began work on making hypertext accessible via a gateway over the Internet. Their written proposal was called “WorldWideWeb: Proposal for a HyperText Project.”

Dec. 25, 1990, they finished the software called WorldWideWeb and had it up-and-running on a CERN computer server.

The next year, they introduced the WorldWideWeb to the internet.

Aug. 6, 1991, is the official date when public computer users outside of CERN were able to use this software over the internet.

Jan. 23, 1993, the web became seen in a whole new light with the release of the first fully-graphical web browser called NCSA Mosaic.

I recall first using the Mosaic version 1.0 client web browser on my HP Omnibook 300 laptop, realizing the internet would never be the same again.

Mosaic was free and could be downloaded from the NCSA website. It included icons, bookmarks, pictures, and an uncomplicated user interface, which made the software easy to use and appealing to the “non-geeks.”

The developers of Mosaic and AOL (America Online) launched the Netscape web browser, which AOL purchased in 1999, for $4.2 billion.

Today, parts of the Mosaic programming language are still used in the popular Mozilla Firefox web browser.

I think of the web as an application program. It contains an information system running as an overlay program on top of the internet; its web elements operating in harmony with today’s internet protocols, which, by the way, were created by Vint Cerf and Robert Kahn.

Today’s web is thriving, with links to millions of data servers providing not only information, but voice, video, social media networks, commerce, government resources, and more.

Tim Berners-Lee’s historic 1989 proposal can be seen on the World Wide Web Consortium’s (W3C) website: https://bit.ly/2eOwOYN.

The web’s beginning started out as a tool to help search for, create, and distribute information for the people working at CERN.

I wonder if Berners-Lee considered the impact on the world his creation would make when he proposed it to CERN 30 years ago?

What will the next 30 years bring?

Stay tuned. 

Photograph by
 User: Coolcaesar at en.wikipedia(This NeXT workstation (a NeXTcube) was used by Tim Berners-Lee as the first Web server on the World Wide Web. Today, it is kept in Microcosm, the public museum at the Meyrin site of CERN, in the Canton of Geneva, Switzerland.)

Mobile Worldwide Congress: ‘Intelligent Connectivity’

©Mark Ollig

Robots handed out cups of freshly-brewed coffee to the human visitors attending one of the world’s largest technology showcases in the Mediterranean seaside city of Barcelona, Spain.

These AI (artificially intelligent) cloud-connected 5G (Fifth generation) mobile robots, built by CloudMinds, also flashed a bit of human emotion, audibly saying, “I screwed up,” whenever they accidentally dropped a cup.

This week, the 2019 MWC (Mobile Worldwide Congress) showcase extravaganza saw more than 107,000 attending what is considered one of the foremost venues for presentations of dominant mobile technology and dazzling digital innovations.

CloudMinds operates these robotic baristas using a unique cloud-to-robot operation platform called Human Augmented Robotics Intelligence with Extreme Reality (HARIX).

HARIX uses an Artificial Intelligence (AI) and a continuously developing “cloud brain,” which has the potential to operate millions of cloud-connected robots over a secured mobile network connection. Yes, “millions.”

AI capabilities, such as Natural Language Processing, Computer Vision and Navigation, and vision-controlled manipulation are included with CloudMinds robots.

CloudMinds sees its AI robots used in customer engagements in hospitality, real-estate, smart cities, and other applications.

At the MWC, phone maker Samsung showed off its newest Galaxy Fold smartphone under glass – with security guarding it as if it was the Mona Lisa.

Look for an April announcement from Samsung on the availability and pricing for the Galaxy Fold.

It was acknowledged during the MWC, that 5G would have a faster deployment rate in the US than in other global markets because of the FCC’s 5G Fast Plan project announced Sept. 28, 2018.

The three central components of the 5G Fast Plan are: pushing more spectrum into the marketplace, updating infrastructure policy, and modernizing outdated regulations.

The FCC says benefits of upgrades of, and installation of new networks and technologies to support 5G include providing low latency (delay of data transfers), resulting in higher mobile/wireless computing performance.

The MWC describes Intelligent Connectivity as the powerful combination of flexible, high-speed 5G networks, IoT (Internet of Things), AI, and “big data.”

For 5G to become a reality for consumers, mobile operators are upgrading their networks with 5G radio spectrum transmitting and receiving gear.

To take advantage of a 5G network, smartphone makers are manufacturing handsets with built-in 5G components.

I believe 5G will be available within many major-populated cities across the country by the end of this year.

Look for 5G to usher us into a world of ultra-high definition video on our smartphones, and devices, and bring in advanced software applications.

Although MWC was focused more on 5G, voice/speech recognition was also showcased.

I recently purchased a Google Home Hub, and have been using it every day for checking the weather, temperature, latest news, Dow Jones, metric conversions, setting a wake-up time, and more.

Sometimes I say, “Hey, Google,” and ask to see a list of synonyms for another word I am trying to come up with when writing a column.

Voice assistance is everywhere. It’s in our homes, cars, offices, smartphones, and is being widely used in the healthcare and other service industries.

Marketing intelligence firm, Tractica forecasts that natural speech recognition will be used by 82 percent of all mobile devices by 2020.

Today, speech recognition has grown beyond its novelty; it’s becoming a regular part of our daily lives, and we will continue to interact with it as we transition into new technologies.

MWC observed milestones in wireless mobile history, including the following:

• Motorola engineer, Martin Cooper made the world’s first call April 3, 1973, in New York City, to a rival competing with him in building the first mobile phone. Cooper’s 3.3-pound handheld mobile phone became known as “The Brick.”

• In 1984, Motorola’s 1.7-pound DynaTAC 8000x became the first commercial portable cellphone available to the public.

• In 1993, Bellsouth and IBM announced their creation of the “personal communicator,” called Simon, which weighed slightly more than 1 pound.

Simon included a pager, email, keypad, automatically updateable calendar, and a stylus for writing on its screen. It was advertised as the world’s first smartphone.

• In 2002, the first phones with built-in cameras became publicly available, including the Nokia 7650 and the Sanyo SPC-5300.

Nokia’s phone camera included a 176x208 pixel color display. Today’s iPhone and Galaxy S9s have eight-megapixels, plus autofocus, flash, and face detection.

Speaking of Apple’s iPhone; it became available in 2007.

In 1988, I bought a Motorola “Bag Phone.” This portable phone was made up of a handset with the keypad on one side, and the traditional receiver/transmitter held up to one’s ear and mouth.

The handset cord was plugged into the same slim transceiver device as was the DC car power source, 12-volt DC 2.3-amp-hour Radio Shack rechargeable battery pack, and “rubber duck” antenna. All of these parts were inside a black nylon bag.

The Motorola Bag Phone also included a coiled antenna attached to a magnet. I would put it on the roof of my car to get a better cellular signal.

In 1977, Motorola began selling their Dimension IV pager. I had one clipped on the pocket of my blue jeans while working at the Winsted Telephone Company, back in the day. I distinctly remember the sound of its audible beeping alert tones.

However, I digress.

As we travel through 2019 toward 2020, we find ourselves on the cusp of a new era being defined as intelligent connectivity. It will be available wherever we are, and whenever we need it.

The MWC official Twitter hashtag is #MWC19. Its website is https://www.mwcbarcelona.com.

Source: MWC19 Barcelona