Electrolytic detector
The electrolytic detector, or the bare-point electrolytic detector as it was also called, was a type of detector (demodulator) used in early radio receivers. First used by Canadian radio researcher Reginald Fessenden in 1903, it was used until about 1913, after which it was superseded by vacuum tube detectors such as the Fleming valve and the Audion. It was considered very sensitive and reliable compared to other detectors available at the time such as the magnetic detector and the coherer.[1] It was one of the first rectifying detectors, able to receive AM (sound) transmissions.
History
While working to develop voice transmission, Reginald Fessenden realised that the radio detectors available would not be suitable for his purpose. Although they worked well for receiving the on-off signals of spark gap transmitters, the coherer and related types of detectors were not, in today's terms, fast enough for receiving audio signals.
In 1902 Fessenden developed what he called a "barretter" detector that would work to receive AM signals, but it was not very sensitive. The barretter used a fine platinum wire, called Wollaston wire, manufactured as a platinum core in a silver sheath that had to be stripped off with acid. In the process of stripping some Wollaston wire, Fessenden left it immersed in acid too long, until only a tip remained in contact with the solution; he noted that it responded well to radio signals being generated nearby, and could be used as new type of detector.
This story was disputed at the time, with credit for the discovery also given to Michael I. Pupin, W. Schloemilch, Hugo Gernsback and others. However, it is apparent that Fessenden was the first to put the device to practical use.
Description
The action of this detector is based upon the fact that only the tip of a platinum wire a few thousandths of an inch in diameter is immersed in an electrolyte solution, and a small D.C. voltage bias is applied to the cell thus formed. Platinum is used because other metals are too quickly dissolved in the acid. The resulting bias current decomposes the solution by electrolysis into tiny gas bubbles that cling to the metal point and tend to insulate the metal tip from the solution thus reducing the bias current. An incoming R.F. current can flow better in the direction across the point that makes the point more negative. That recombines the gases and increases point exposure to the liquid. RF current flow in the direction that makes the point more positive only reinforces gaseous blocking of the point. Detection results from this asymmetrical flow.
In practical use a series circuit is made of the detector, headphones, and a battery with a potentiometer. The wire is made positive, and the signal to be demodulated is applied directly to it; a small (about 5 ml) platinum cup filled with either sulfuric or nitric acid completes the headphone circuit, and is also connected to ground to complete the signal circuit. To adjust the cell, the point of the wire electrode is dipped into the electrolyte and the potentiometer adjusted until a hissing noise is heard in the headphones; the potentiometer is then moved back until the noise just ceases, at which point the detector is in its most sensitive state.
It was found that strong atmospheric noise would render it insensitive, requiring that the device be rebiased after each strong burst of static interference.
Sealed-point detector
Another form of electrolytic detector, the sealed-point electrolytic detector, which could stand considerable rough usage, was commercially known as the Radioson Detector; it had the cell sealed in a glass envelope. The operation was the same as in the bare-point electrolytic detector, the advantage being that the acid was sealed in, and consequently could not spill or evaporate.
See also
Notes
- ^ Belrose, John S. (5–7 September 1995). "Receiver Technology". International Conference on 100 Years of Radio. IEEE. Retrieved 28 July 2010.
External links
