A. History of Telecommunications

Chapter Objectives

  • A-1 Summarize the history of telecommunications, from ancient signaling methods such as smoke signals and drum beating to modern-day technologies.
  • A-2 Describe the inventions of the telegraph and telephone and the key contributors to the development of these technologies.
  • A-3 Explain the role of submarine cables in the early transatlantic telecommunications.
  • A-4 Explore the history of radio and television, including the contributions of major inventors, practitioners, and researchers.
  • A-5 Chart the widespread adoption of videotelephony through videoconferencing, webcams, and telepresence technology.

Signals and Codes

In this introduction, we take a brief tour of telecommunications through videotelephony.

Optical Telegraphy

Communications signaling is an ancient as the smoke signals and drum beating of early civilizations. The history of modern telecommunications, however, began with the use of the telegraph to transmit signals by transit systems such as railroads.

Experiments on communication with electricity, initially unsuccessful, started in about 1726. Scientists including Laplace, Ampère, and Gauss were involved. The first working telegraph was built by Francis Ronalds in 1816 and used static electricity. Charles Wheatstone and William Fothergill Cooke patented a five-needle, six-wire system, which entered commercial use in 1838. This system used the deflection of needles to represent messages and started operating over twenty-one kilometers (thirteen miles) of the Great Western Railway on 9 April 1839.

On the other side of the Atlantic Ocean, Samuel Morse developed a version of the electrical telegraph, which he demonstrated on September 2, 1837. Alfred Vail saw this demonstration and joined Morse to develop the register—a telegraph terminal that integrated a logging device for recording messages to paper tape. This was demonstrated successfully over three miles (five kilometers) on January 6, 1838 and eventually over forty miles (sixty-four kilometers) between Washington, D.C. and Baltimore on May 24, 1844. Morse’s most important technical contribution to this telegraph was the simple and highly efficient Morse code, co-developed with Vail, which was an important advance over Wheatstone’s more complicated and expensive system, and required just two wires. The communications efficiency of the Morse Code preceded that of the Huffman code in digital communications by over 100 years, but Morse and Vail developed the code purely empirically, with shorter codes for more frequent letters.

The first successful transatlantic telegraph cable was laid in 1858, allowing for near real-time communication between North America and Europe for the first time. However, this initial cable quickly failed after just a few weeks of operation due to technical issues. After several failed attempts, a more reliable and improved transatlantic cable was successfully completed in 1866, ushering in the era of transoceanic communications. This 1866 cable used advanced insulation and transmission technologies that increased transmission speeds to around 8 words per minute, a vast improvement over the 1858 cable. These early submarine telegraph cables, while slow by today’s standards, enabled rapid communication over long distances for the first time in history. They fueled globalization by allowing businesses, governments and individuals to exchange information across oceans nearly instantaneously, revolutionizing global trade and diplomacy. The success of the 1866 cable led to the laying of several more transatlantic cables in the following decades, creating a “web” of submarine telegraph cables that formed an early global communications network based on Morse code.

Concepts Corner

What is Morse code and Huffman code?

Morse Code

Morse Code is a method of encoding textual information into sequences of dots (short signals) and dashes (long signals). It uses a set of standardized sequences for each letter of the alphabet, numerals, and some punctuation marks, as shown below.

  • Dots and Dashes: Represented as “.” (dot) and “-” (dash). A dot is typically a short signal, while a dash is longer.
  • Timing: The duration of a dash is typically three times that of a dot. Spaces between dots and dashes within a character are the length of one dot, while spaces between characters are the length of three dots. Words are separated by a space equivalent to seven dots.
  • Usage: Originally used for telegraphy, it later found use in radio communications and is still recognized for its utility in emergency signaling.

Huffman Code

Huffman coding is an algorithm used for lossless data compression, including file compression algorithms like JPEG, MP3, and in some implementations of the ZIP file format. Unlike Morse Code, which uses fixed-length signals, Huffman coding generates variable-length codes based on the frequency of occurrence of each symbol in the source data. Symbols that occur more frequently are assigned shorter codes, while less frequent symbols get longer codes, with these two concepts. Huffman code is used today to transmit huge amounts of information.

  • Frequency-Based Encoding: The length of each code is inversely proportional to the frequency of the symbol it represents.
  • Binary Tree: A binary tree is constructed from the bottom up, where each leaf node represents a symbol and its frequency. The tree’s structure ensures that no code is a prefix of another, maintaining the uniqueness and decodability of the data.

See this video by Aloe Blacc for a high-level view of compression.

“Tele”nologies

Telephone

The electric telephone was invented in the 1870s, it was based on earlier work with harmonic telegraphs. The first commercial telephone services were set up in 1878 and 1879 on both sides of the Atlantic in the cities of New Haven and London. Alexander Graham Bell held the master patent for the telephone that was needed for such services in both countries. As with other great inventions such as radio, television, the light bulb, and the digital computer, several inventors engaged in pioneering experimental work on voice transmission over a wire, and then improved on each other’s ideas. However, the key innovators were Alexander Graham Bell and Gardiner Greene Hubbard, who created the first telephone company, the Bell Telephone Company in the United States, which later evolved into American Telephone & Telegraph (AT&T), which was, at times, the world’s largest phone company.

Telephone technology grew quickly after the first commercial services emerged, with inter-city lines being built and telephone exchanges in every major city of the United States by the mid-1880s. The first transcontinental telephone call occurred on January 25, 1915. Despite this, transatlantic voice communication remained impossible for customers until January 7, 1927 when a connection was established using radio. However, no cable connection existed until TAT-1 was inaugurated on September 25, 1956 providing 36 telephone circuits.

In 1880, Bell and co-inventor Charles Sumner Tainter conducted the world’s first wireless telephone call via modulated light beams projected by photophones. The scientific principles of their invention would not be utilized for several decades, when they were first deployed in military and fiber-optic communications.

The first transatlantic telephone cable (which incorporated hundreds of electronic amplifiers was not operational until 1956, only six years before the first commercial telecommunications satellite, Telstar, was launched into space.

“History of Telecommunications” by General Post Office. The National Communications Museum collection 8817 (December 8, 2020). Licensed under CC BY 4,0.

Radio and Television

Over several years starting in 1894, the Italian inventor Guglielmo Marconi worked on adapting the newly discovered phenomenon of radio waves to telecommunication, building the first wireless telegraphy system using them. In December 1901, he established wireless communication between St. John’s, Newfoundland and Poldhu, Cornwall (England), earning him a Nobel Prize in Physics (which he shared with Karl Braun) in 1909. In 1900, Reginald Fessenden was able to wirelessly transmit a human voice.

In 1925, Japanese engineerKenjiro Takayanagi demonstrated a CRT television with thermal electron emission. In 1927, he increased the television resolution to 100 lines, which was unrivaled until 1931. In 1928, he was the first to transmit human faces in half-tones on television, influencing the later work of Vladimir K. Zworykin.

On March 25, 1925, Scottish inventor John Logie Baird publicly demonstrated the transmission of moving silhouette pictures at the London department store Selfridge’s. Baird’s system relied upon the fast-rotating Nipkow disk, and thus it became known as the mechanical television. His invention formed the basis of semi-experimental broadcasts done by the British Broadcasting Corporation beginning September 30, 1929.

For most of the twentieth century, televisions used the cathode ray tube (CRT) invented by Karl Braun. In 1934, he gave the first public demonstration of the television at Philadelphia’s Franklin Institute and opened his own broadcasting station. John Logie Baird switched from mechanical television and became a pioneer of color television using cathode-ray tubes. After mid-century, the spread of coaxial cable and microwave radio relay allowed television networks to spread across even large countries.

Videotelephony

The development of videotelephony involved the historical development of several technologies, which enabled the use of live video in addition to voice telecommunications. The concept of videotelephony was first popularized in the late 1870s in both the United States and Europe, although the basic sciences to permit its very earliest trials would take nearly a half century to be discovered. This was first embodied in the device which came to be known as the video telephone, or videophone, and it evolved from intensive research and experimentation in several telecommunication fields, notably electrical telegraphy, telephony, radio, and television.

The development of the crucial video technology first started in the latter half of the 1920s in the United Kingdom and the United States, spurred notably by John Logie Baird and AT&T’s Bell Labs. This occurred in part, at least by AT&T, to serve as an adjunct supplementing the use of the telephone. A number of organizations believed that videotelephony would be superior to plain voice communications. However video technology was to be deployed in analog television broadcasting long before it could become practical—or popular—for videophones.

Videotelephony developed in parallel with conventional voice telephone systems from the mid-to-late 20th century. Only in the late 20th century with the advent of powerful video codecs and high-speed broadband did it become a practical technology for regular use. With the rapid improvements and popularity of the Internet, it became widespread through the use of videoconferencing and webcams, which frequently utilize Internet telephony, and in business, where telepresence technology has helped reduce the need to travel.

Adapted from “History of Telecommunications” by Scholarly Encyclopedia Community and licensed under CC BY-NC-SA 4.0 / A derivative from the original work

Discussion Topics

  1. How do ancient signaling methods, such as smoke signals and drum beats, compare to the ways you communicate with friends and family today?
    • Reflect on the evolution from these early methods to modern digital communication tools like social media and messaging apps.
  2. What technological advancements in telecommunications have had the most significant impact on your daily life as a student?
    • Consider how inventions like the internet, smartphones, and video calls have transformed your study habits, social interactions, and access to information.
  3. How has the development of videotelephony, such as Zoom and Microsoft Teams, changed your experience of attending classes and collaborating on projects?
    • Discuss the benefits and challenges of using these technologies for remote learning and teamwork.

License

Icon for the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License

Telecommunications and Networking Copyright © by Rita Mitra; Glenn Brown; Melanie Huffman; and Hongyi Zhu is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License, except where otherwise noted.

Share This Book