Arc converter

1 megawatt Poulsen arc transmitter used by the U.S. Navy around 1918 in shore radio stations to communicate with its fleet worldwide, one of the largest arc transmitters ever built.

The arc converter, sometimes called the arc transmitter, or Poulsen arc after Danish engineer Valdemar Poulsen who invented it in 1903,[1][2] was a variety of spark transmitter used in early wireless telegraphy. The arc converter used an electric arc to convert direct current electricity into radio frequency alternating current. It was used as a radio transmitter from 1903 until the 1920s when it was replaced by vacuum tube transmitters. One of the first transmitters that could generate continuous sinusoidal waves, it was one of the first technologies used to transmit sound (amplitude modulation) by radio. It is on the list of IEEE Milestones as a historic achievement in electrical engineering.[3]

History

Poulsen's first arc converter, from 1903
Circuit of basic arc converter, from Poulsen's 1904 paper (labels added).

Elihu Thomson discovered that a carbon arc shunted with a series tuned circuit would "sing". This "singing arc" was probably limited to audio frequencies.[4] Bureau of Standards credits William Duddell with the shunt resonant circuit around 1900.[5]

The English engineer William Duddell discovered how to make a resonant circuit using a carbon arc lamp. Duddell's "musical arc" operated at audio frequencies, and Duddell himself concluded that it was impossible to make the arc oscillate at radio frequencies.

Valdemar Poulsen, who had demonstrated the 'Telegraphone' (the world's first magnetic recording device) at the Paris Exhibition of 1900, succeeded in raising the efficiency and frequency to the desired level. Poulsen's arc could generate frequencies of up to 200 kilohertz and was patented in 1903.

After a few years of development the arc technology was transferred to Germany and Great Britain in 1906 by Poulsen, his collaborator Peder Oluf Pedersen and their financial backers. In 1909 the American patents as well as a few arc converters were bought by Cyril F. Elwell. The subsequent development in Europe and the United States was rather different, since in Europe there were severe difficulties for many years implementing the Poulsen technology, whereas in the United States an extended commercial radiotelegraph system was soon established with the Federal Telegraph Company. Later the US Navy also adopted the Poulsen system. Only the arc converter with passive frequency conversion was suitable for portable and maritime use. This made it the most important mobile radio system for about a decade until it was superseded by vacuum tube systems.

In 1922, the Bureau of Standards stated, "the arc is the most widely used transmitting apparatus for high-power, long-distance work. It is estimated that the arc is now responsible for 80 per cent of all the energy actually radiated into space for radio purposes during a given time, leaving amateur stations out of consideration."[6]

Description

Unlike the existing radio transmitter of the time, the spark-gap transmitter, the arc converter produces undamped or continuous waves (CW). This was an important feature as the use of damped waves resulted in lower transmitter efficiency and communications effectiveness, while covering the RF spectrum with interference. This more refined method for generating continuous-wave radio signals was initially developed by Danish inventor Valdemar Poulsen.

There are three cases for an arc oscillator.[7] In the first case, the AC current in the condenser i0 is much smaller than the DC supply current i1, and the arc is never extinguished during an output cycle. The Duddell arc is an example of the first case, but the first case is not practical for RF transmitters. In the second case, the condenser AC discharge current is large enough to extinguish the arc but not large enough to restart the arc in the opposite direction. This second case is the Poulsen arc. In the third case, the arc extinguishes but may reignite when the condenser current reverses. The third case is a quenched spark gap and produces damped oscillations.

The Poulsen arc converter has a tuned circuit connected across the arc. The arc converter consisted of a chamber in which the arc burned in hydrogen gas between a carbon cathode and a water-cooled copper anode. Above and below this chamber there were two series field coils surrounding and energizing the two poles of the magnetic circuit. These poles projected into the chamber, one on each side of the arc to provide a magnetic field.

It was most successful when operated in the frequency range of a few kilohertz to a few tens of kilohertz. The antenna tuning had to be selective enough to suppress the harmonic output of the arc converter.

Keying

Since the arc took some time to strike and operate in a stable fashion, normal on-off keying could not be used. Instead, a form of frequency shift keying was employed.[8] In this compensation-wave method, the arc operated continuously, and the key altered the frequency of the arc by one to five percent. The signal at the unwanted frequency was called the compensation-wave. In arc transmitters up to 70 kW, the key typically shorted out a few turns in the antenna coil.[9] For larger arcs, the arc output would be transformer coupled to the antenna inductor, and the key would short out a few bottom turns of the grounded secondary.[10] Therefore, the "mark" (key closed) was sent at one frequency, and the "space" (key open) at another frequency. If these frequencies were far enough apart, and the receiving station's receiver had adequate selectivity, the receiving station would hear standard CW when tuned to the "mark" frequency.

The compensation wave method used a lot of spectrum bandwidth. It not only transmitted on the two intended frequencies, but also the harmonics of those frequencies. Arc converters are rich in harmonics. Sometime around 1921, the Preliminary International Communications Conference[11] prohibited the compensation wave method because it caused too much interference.[4]

The need for the emission of signals at two different frequencies was eliminated by the development of uniwave methods.[12] In one uniwave method, called the ignition method, keying would start and stop the arc. The arc chamber would have a striker rod that shorted out the two electrodes through a resistor and extinguished the arc. The key would energize an electromagnet that would move the striker and reignite the arc. For this method to work, the arc chamber had to be hot. The method was feasible for arc converters up to about 5 kW.

The second uniwave method is the absorption method, and it involves two tuned circuits and a single-pole, double-throw, make-before-break key. When the key is down, the arc is connected to the tuned antenna coil and antenna. When the key is up, the arc is connected to a tuned dummy antenna called the back shunt. The back shunt was a second tuned circuit consisting of an inductor, a capacitor, and load resistor in series.[13][14] This second circuit is tuned to roughly the same frequency as the transmitted frequency; it keeps the arc running, and it absorbs the transmitter power. The absorption method is apparently due to W. A. Eaton.[4]

The design of switching circuit for the absorption method is significant. It is switching a high voltage arc, so the switch's contacts must have some form of arc suppression. Eaton had the telegraph key drive electromagnets that operated a relay. That relay used four sets of switch contacts in series for each of the two paths (one to the antenna and one to the back shunt). Each relay contact was bridged by a resistor. Consequently, the switch was never completely open, but there was a lot of attenuation.[15]

See also

References

  1. US 789449, Poulsen, Valdemar, "Method of producing alternating currents with a high number of vibrations", published 10 June 1903, issued 9 May 1905
  2. Poulsen, Valdemar (12 September 1904). "System for producing continuous electric oscillations". Transactions of the International Electrical Congress, St. Louis, 1904, Vol. 2. J. R. Lyon Co. pp. 963–971. Retrieved 22 September 2013.
  3. "Milestones:Poulsen-Arc Radio Transmitter, 1902". IEEE Global History Network. IEEE. Retrieved 29 July 2011.
  4. 1 2 3 Little 1921, p. 125
  5. Bureau of Standards 1922, p. 404
  6. Bureau of Standards 1922, p. 400
  7. Bureau of Standards 1922, p. 404–405
  8. Bureau of Standards 1922, pp. 415416
  9. Bureau of Standards 1922, figure 228. The series resonant tuned circuit would be the antenna coil in series with the antenna.
  10. Bureau of Standards 1922, figure 229
  11. Possibly the Preliminary International Conference on Electrical Communications, 1920; see http://www.archives.gov/research/guide-fed-records/groups/043.html at 43.2.11
  12. Bureau of Standards 1922, pp. 416419
  13. Bureau of Standards 1922, figure 229-A
  14. Eaton 1921
  15. Eaton 1921, p. 115

Further reading

External links

Wikimedia Commons has media related to Spark-gap transmitters.
This article is issued from Wikipedia - version of the Monday, December 14, 2015. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.