Amateur Radio and UNIVAC and the 1952 Presidential Election: Difference between pages

From ETHW
(Difference between pages)
No edit summary
 
m (<replacetext_editsummary>)
 
Line 1: Line 1:
== Amateur Radio&nbsp;  ==
== UNIVAC and the 1952 Presidential Election ==


[[Image:Amatuerradiostamp.jpg|thumb|left]]
The story has been told and retold for decades: how CBS Television News used a [[UNIVAC]] computer to predict the 1952 U.S. Presidential election returns and — when the computer accurately predicted the Eisenhower landslide at around 8:30 in the election night broadcast — the prediction was doubted, and only hours later did CBS reveal that the prediction had been accurate. It has become a classic cautionary tale of the dangers of allowing human preconception to interfere with logic and evaluation of facts.


A retired military officer in North Carolina makes friends over the radio with an amateur radio operator (known the world over as “hams”) in Lithuania. An Ohio teenager uses her computer to upload a chess move to an orbiting space satellite, where it’s retrieved by a fellow chess enthusiast in Japan. In California, volunteers save lives as part of their involvement in an emergency communications network. And at the scene of a traffic accident on a Chicago freeway, a ham calls for help by using a pocket-sized hand-held radio.&nbsp;
There is more to the story. The exact timeline of when UNIVAC's initial prediction was made is not certain, but what is important is that UNIVAC's correct prediction of a landslide victory was ostensibly ignored until much later in the broadcast because of journalistic prudence and lack of confidence in the accuracy of the results.


This unique mix of fun, public service, and convenience is the distinguishing characteristic of amateur radio. Some hams are attracted to the idea of communicating across the country, around the globe, and even with astronauts on space missions. Others enjoy building and experimenting with electronics. Although hams get involved in the hobby for many reasons, all have a basic knowledge of radio technology, regulations, and operating principles and must pass an examination for a license to operate on radio frequencies known as the amateur bands. [[Image:Amateur_radio_78.jpg|thumb|right|A pair of 7800's]]
Dr. Ira Chinoy, whose doctoral thesis examines the use of computers in broadcast journalism, estimates that the celebrated initial prediction of the Eisenhower landslide was made closer to 9:15.  At 8:30, only slightly more than one million votes had been tallied; it took until at least 9:15 pm for three million votes to be transmitted from CBS to the Remington Rand factory in Philadelphia. CBS was receiving vote tallies from the wire services and teletyping them to Remington Rand’s factory in Philadelphia. Additional time was needed to input the data and to run the programs.


Amateur radio is as old as radio itself. Not long after Italian experimenter Guglielmo Marconi transmitted the [[Morse Code|Morse Code]] letter “s” from Wales to Newfoundland, Canada in 1901, amateur experimenters throughout the world were trying out the capabilities of the first [[Spark Transmitter|“spark gap” transmitters]]. In 1912 Congress passed the first laws regulating radio transmissions in the United States. By 1914 amateur experimenters were communicating nationwide, and setting up a system to relay messages from coast to coast. In 1927 Congress created the precursor agency to the Federal Communications Commission (FCC) and specific frequencies were assigned for various uses, including ham bands.  
The 8:30 CBS segment merely gave the television audience a visual tour and introduction to UNIVAC; the second UNIVAC segment of the evening at 9:30 asked for a prediction, but the machine was not yet ready. By that point in the television coverage, the human commentators were already commenting on the surprising Eisenhower strength in the early returns. On the basis of pre-election polls, the race between Eisenhower and Stevenson had seemed to be close (Eisenhower held a slight edge), so the use of a state-of-the-art computer to predict what was expected to be a very close election had generated a lot of popular interest.


If you were to look at the dial on an old AM radio you’d see frequencies marked from 535 to 1605 kilohertz (kHz). Imagine that band extended out many thousands of kilohertz, and you’ll have some idea of how much additional radio spectrum is available for amateur, government, and commercial radio bands. It is here you’ll find aircraft, ship, fire and police communication, as well as the so-called “shortwave” stations, which are worldwide commercial and government broadcast stations from the U.S and overseas. Amateurs are allocated nine basic “bands” (i.e,. groups of frequencies) in the High Frequency (HF) range between 1800 and 29,700 kHz, and another seven bands in the Very High Frequency (VHF) and Ultra High Frequency (UHF) ranges. There are nine more segments in the Super High Frequency (SHF) and Extremely High Frequency (EHF) microwave bands. Finally, hams can use any frequency above 300 gigahertz (GHz)!
At some point relatively early in the evening, UNIVAC predicted an Eisenhower landslide victory. However, the UNIVAC programmers decided that the prediction was too risky to release because it contradicted what the pollsters had been saying previous to the election about a tight race.


At 10:30, which was the third on-air UNIVAC segment, the computer predicted twenty-eight states for Eisenhower and twenty for Stevenson. This was a softer prediction, and was in line with what the CBS commentators had already been telling their television audience. It was the initial correct prediction of an overwhelming Eisenhower win that the UNIVAC programmers decided not to release because it contradicted the poll numbers.


The 11:30 UNIVAC on-air prediction caused more drama. It reversed its earlier prediction, calling 24 states each for Eisenhower and Stevenson, and a slim 270 to 261 Electoral College vote margin for Eisenhower.  But by 11:45, the prediction had been corrected and UNIVAC predicted 100 to 1 odds of an Eisenhower victory.


Given the right frequency and propagation conditions, amateur radio conversations can take place across town and around the world. Those with a competitive streak enjoy amateur radio contests, where the object is to see how many hams they can contact in a certain time, often a weekend. Some like the convenience of a technology that gives them portable communication. Others use it to open the door to new friendships over the air or through participation in one of thousands of amateur radio clubs throughout the world.
UNIVAC made its predictions based on the difference between vote tallies and the expected vote in cities and counties, based on a statistical model extrapolated from past elections. By applying this deviation in places that had already voted to those which had not yet voted, an estimate of the present election could be obtained based on past tallies in those places. One of the ironies of the election of 1952 was that the returns from Massachusetts, one of the crucial early-reporting states, were incorrectly reported to UNIVAC.  That UNIVAC was nonetheless able to make accurate predictions.


== Governing Bodies  ==
The UNIVAC used by CBS was the fifth UNIVAC machine made. In the autumn of 1952, UNIVAC-5 was still in the Philadelphia factory of Remington Rand waiting for its future installation at the Lawrence Livermore Laboratories. Because UNIVAC itself was too large to be moved conveniently, a dummy control console was set up in the CBS studio in [[Grand Central Terminal]], New York City for visual effect, its lights blinking evocatively thanks to delay switches ordinarily used for making Christmas tree lights flash on and off.


Amateur radio is largely governed globally by the [[International Amateur Radio Union|International Amateur Radio Union (IARU)]], a representative body in the ITU. The IARU comprises representatives from each of the national bodies, eg ARRL in the US, WIA in Australia, PZK in Poland, SARTS in Singapore, MARTS in Malaysia, JARL in Japan, NZART in New Zealand. [and more].  
There was some irony that a machine which debuted in the public spotlight of national TV would go on to do classified weapons work.  UNIVAC contained mercury delay lines, which allowed it to store 1,000 words (45 bits each) as electric pulses in tubes of mercury. Up to one million characters could be stored and accessed on magnetic tape. It was these tapes, replacing punched cards, which made the UNIVAC revolutionary, and which gave it a tremendous speed advantage because it could access its own data instead of needing to wait for cards to be loaded. It could perform four hundred and sixty-five multiplications per second and had a clock speed of 2.25MHz.


Individual PTT's directly regulate licensing in each Country, examples are FCC (in the USA), ACMA (Australia), Post Office (Solomon Islands), [and more ].
== Video ==


Licensing in the United States began with the [[Radio Act of 1912]].
A brief video of the CBS prediction can be seen here.


== Spinoffs  ==
{{#widget:YouTube16x9|id=v7K8MW8wQWs</youtube>


There have been some amazing business spinoffs generated by amateur radio enthusiasts, the [[Electron (or Vacuum) Tubes|vacuum tube]] manfacturer [[Eimac|Eimac]], ICOM, Yaesu, Codan and probably others. See the [[Hy-Gain_TH7DX_Antenna|Hy-gain TH7DX]] antenna story.
== Further Reading ==


Additionally there have been some remarkable explorations into communications, eg, EME Communications, super low bandwidth communications (approx 6Hz channel bandwidth) , eg WSJT, PSK31 (approx 50hz channel bandwidth), etc.  
[http://drum.lib.umd.edu/bitstream/1903/10504/1/Chinoy_umd_0117E_11395.pdf Ira Chinoy's doctoral thesis]


[[Image:Amateur radio basic.jpg|thumb|right|A basic ham station used in a field day portable capacity.]]
[[Category:Computing and electronics]]
 
[[Category:Computer_science]]
== Amateur Radio Callsigns  ==
 
[[Callsign History - Australia|AUSTRALIA]]
 
INDIA -&nbsp;http://en.wikipedia.org/wiki/Amateur_radio_callsigns_of_India
 
USA -&nbsp;http://earlyradiohistory.us/recap.htm<br>
 
== EMR Safety Calculator / RF&nbsp;Safety Calculator  ==
 
Amateur Radio operators are required to perform EMR Safety Calculations, that control the safe exposure distances to controlled and uncontrolled radio frequency (or EMF) environments. These safety calculations and resultant compliance requirements have largely become mandatory by most regulators. The operator&nbsp;can be&nbsp;asked to produce these calculations when requested by the regulator. The FCC introduced it in 1997, New Zealand in 2000 and Australia in 2002.
 
*The following spreadsheet replicates <u>ALL</u> the regulators tables / formulas and complex safety distance lookup tables found in both the FCC, New Zealand and Australian requirements. It also covers power levels in excess of that legally permitted, as well as the safety calculation for 60m (5MHz) frequency band (which is not part of any guideline currently). Please read the notes and exclusions in the spreadsheet notes page.
 
[[Media:Copy_of_RF_EMR_Exposure_Compliance_publish_draft5.xls|RF EMR Safety Exposure Calculator]] (xls)
 
This spreadsheet calculator addresses the Amateur Radio Operator RF&nbsp;Safety compliance obligations to the following guidelines/standards:
 
*Australia - Human Exposure to EMR: Assessment of Amateur Radio Stations for Compliance with ACA Requirements, May 2005, version 2.0
*USA - FCC Sup B to OET B65 Ed97-01
*New Zealand - NZS2772-1999
 
== Further reading:  ==
 
[[First-Hand:It Started with Ham Radio|It Started with Ham Radio]], a First Hand History by Pete Lefferson
 
[[Media:1907_wireless_licence_application.pdf|1907 Wireless Licence application form]] (pdf)<br>[[Media:Amateur_radio_78.jpg|Amateur radio IC-7800's photo]]
 
'''This site is made possible by donations. If you find these articles valuable, please consider supporting the IEEE History Center’s work by making a donation to
[https://www.ieee.org/organizations/foundation/DonateOnline.html#| IEEE Foundation - History Center Fund]'''.  There is a box marked “Designations” with an arrow which allows you to assign your gift to the History Center.
 
[[Category:Radio_broadcasting]]

Revision as of 21:20, 6 January 2015

UNIVAC and the 1952 Presidential Election

The story has been told and retold for decades: how CBS Television News used a UNIVAC computer to predict the 1952 U.S. Presidential election returns and — when the computer accurately predicted the Eisenhower landslide at around 8:30 in the election night broadcast — the prediction was doubted, and only hours later did CBS reveal that the prediction had been accurate. It has become a classic cautionary tale of the dangers of allowing human preconception to interfere with logic and evaluation of facts.

There is more to the story. The exact timeline of when UNIVAC's initial prediction was made is not certain, but what is important is that UNIVAC's correct prediction of a landslide victory was ostensibly ignored until much later in the broadcast because of journalistic prudence and lack of confidence in the accuracy of the results.

Dr. Ira Chinoy, whose doctoral thesis examines the use of computers in broadcast journalism, estimates that the celebrated initial prediction of the Eisenhower landslide was made closer to 9:15. At 8:30, only slightly more than one million votes had been tallied; it took until at least 9:15 pm for three million votes to be transmitted from CBS to the Remington Rand factory in Philadelphia. CBS was receiving vote tallies from the wire services and teletyping them to Remington Rand’s factory in Philadelphia. Additional time was needed to input the data and to run the programs.

The 8:30 CBS segment merely gave the television audience a visual tour and introduction to UNIVAC; the second UNIVAC segment of the evening at 9:30 asked for a prediction, but the machine was not yet ready. By that point in the television coverage, the human commentators were already commenting on the surprising Eisenhower strength in the early returns. On the basis of pre-election polls, the race between Eisenhower and Stevenson had seemed to be close (Eisenhower held a slight edge), so the use of a state-of-the-art computer to predict what was expected to be a very close election had generated a lot of popular interest.

At some point relatively early in the evening, UNIVAC predicted an Eisenhower landslide victory. However, the UNIVAC programmers decided that the prediction was too risky to release because it contradicted what the pollsters had been saying previous to the election about a tight race.

At 10:30, which was the third on-air UNIVAC segment, the computer predicted twenty-eight states for Eisenhower and twenty for Stevenson. This was a softer prediction, and was in line with what the CBS commentators had already been telling their television audience. It was the initial correct prediction of an overwhelming Eisenhower win that the UNIVAC programmers decided not to release because it contradicted the poll numbers.

The 11:30 UNIVAC on-air prediction caused more drama. It reversed its earlier prediction, calling 24 states each for Eisenhower and Stevenson, and a slim 270 to 261 Electoral College vote margin for Eisenhower. But by 11:45, the prediction had been corrected and UNIVAC predicted 100 to 1 odds of an Eisenhower victory.

UNIVAC made its predictions based on the difference between vote tallies and the expected vote in cities and counties, based on a statistical model extrapolated from past elections. By applying this deviation in places that had already voted to those which had not yet voted, an estimate of the present election could be obtained based on past tallies in those places. One of the ironies of the election of 1952 was that the returns from Massachusetts, one of the crucial early-reporting states, were incorrectly reported to UNIVAC. That UNIVAC was nonetheless able to make accurate predictions.

The UNIVAC used by CBS was the fifth UNIVAC machine made. In the autumn of 1952, UNIVAC-5 was still in the Philadelphia factory of Remington Rand waiting for its future installation at the Lawrence Livermore Laboratories. Because UNIVAC itself was too large to be moved conveniently, a dummy control console was set up in the CBS studio in Grand Central Terminal, New York City for visual effect, its lights blinking evocatively thanks to delay switches ordinarily used for making Christmas tree lights flash on and off.

There was some irony that a machine which debuted in the public spotlight of national TV would go on to do classified weapons work. UNIVAC contained mercury delay lines, which allowed it to store 1,000 words (45 bits each) as electric pulses in tubes of mercury. Up to one million characters could be stored and accessed on magnetic tape. It was these tapes, replacing punched cards, which made the UNIVAC revolutionary, and which gave it a tremendous speed advantage because it could access its own data instead of needing to wait for cards to be loaded. It could perform four hundred and sixty-five multiplications per second and had a clock speed of 2.25MHz.

Video

A brief video of the CBS prediction can be seen here.

{{#widget:YouTube16x9|id=v7K8MW8wQWs</youtube>

Further Reading

Ira Chinoy's doctoral thesis

Retrieved from "https://ethw.org/w/index.php?title=Amateur_Radio&oldid=109905"

Powered by MediaWiki
Powered by Semantic MediaWiki