Historical cat's whisker designs: Difference between revisions
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Created page with "right Crystal radios from the 1920s are possible to get hold of, but can be quite expensive. This is a collection of photographs and diagrams of crystal/cat's whiskers setups that I've managed to find. The materials used correspond with what was available at the time, glass, metal but also the first plastics, ebonite and bakelite - which would have felt very futuristic in these years. On the right is a diagram of a vertical set up. This..." |
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[[File:Catswhiskerdiagram.png|right]] | [[Category:ACE R&D]] | ||
[[File:Catswhiskerdiagram.png|200px|right]] | |||
Crystal radios from the 1920s are possible to get hold of, but can be quite expensive. This is a collection of photographs and diagrams | Crystal radios from the 1920s are still possible to get hold of, but can be quite expensive. They contain a wide variety of approaches to mounting a crystal (usually, but not exclusively galena) and the cat's whisker, and attempts at making them adjustable and adding stability at the same time. This is a collection of photographs and diagrams I've managed to find online. The materials used correspond with what was available at the time, glass and metal but also the first plastics, ebonite and bakelite - which would have felt very futuristic in these years. | ||
On the right is a diagram of a vertical set up. This design doesn't seem to allow for positioning of the point contact, only the overall pressure - which is generally more important. | On the right is a diagram of a vertical set up found on [https://www.radiomuseum.org|radiomuseum.org]. This design doesn't seem to allow for positioning of the point contact, only the overall pressure - which to be fair is generally more important. | ||
==Historical variants found on ebay listings== | |||
Ebay is a good resource for images of different variants of cat's whisker apparatus. This is the galena point contact diode described in [[Semiconductor history]] and is a typical form found in (usually I think) British made crystal radios. | |||
[[File:Radio-close.jpg]] | |||
It's a horizontal setup and protects the crystal with a glass envelope. You can clearly see a direct link to modern components like this germanium diode, which still uses the point contact idea - but is fixed and much smaller: | |||
[[File:EFD108_Point_Contact_Germanium_Diode.jpg|200px|thumb|left|Mister rf, CC BY-SA 4.0 <https://creativecommons.org/licenses/by-sa/4.0>, via Wikimedia Commons|500px]] | |||
This is another variant of the horizontal construction, there were probably as many varieties of these as there were companies manufacturing radios (several hundred) including home made designs. | |||
[[File:Horizontal.jpg]] | |||
The other common approach was to mount the crystal at right angles to the 'arm' and allow it to be adjusted in a similar way, but pointing down on the crystal. These tend not to be enclosed in glass, and seem (as far as I can tell) to be slightly more common in the USA. | |||
[[File:ArmType.webp|500px|center]] | |||
===Multi crystal sets=== | |||
Many radios feature multiple crystals and a switch to select which one to use. This is presumably an indication of their unreliability and drift over time - something I have also experienced in use in audio circuits. You could use one for a bit and then switch to the other, perhaps for different frequencies - although I feel the advantages may have been more imagined if they were using galena for both. Given that the mechanism causing semiconducting were not understood at the time, this may have been understandable. | |||
[[File:Double.jpg|center]] | |||
This is a piece of equipment specifically for testing crystals. It's unclear but possibly the one on the left is for testing two crystals brought into contact with each other. "Perikon" was the name given to combining chalcopyrite and zincite, which was made in this way. | |||
[[File:Multi.webp]] | |||
Sometimes different types of crystal could be switched between in a radio. This Marconi Marconiphone "Crystal A" type RB3 radio set from 1922, which seems so different in it's construction methods to those of today it almost invites a comparison to be drawn to quantum computing technology. It has two rectifier options: galena, as we have seen already - and carborundum (silicon carbide), which is very rare in nature but is created via industrial processes for many uses due to its relative hardness. | |||
[[File:Marconi.webp]] | |||
Instead of a cat's whisker, the carborundum is fashioned into a point that makes contact with a metal plate - so the inverse of the galena point contact. The contact pressure can be adjusted with a thumb screw - this image show the parts disassembled. It seems a common feature of these devices to be easily | |||
[[File:Marconi2.webp]] | |||
==Modern builds== | |||
Revision as of 09:01, 21 June 2026
Crystal radios from the 1920s are still possible to get hold of, but can be quite expensive. They contain a wide variety of approaches to mounting a crystal (usually, but not exclusively galena) and the cat's whisker, and attempts at making them adjustable and adding stability at the same time. This is a collection of photographs and diagrams I've managed to find online. The materials used correspond with what was available at the time, glass and metal but also the first plastics, ebonite and bakelite - which would have felt very futuristic in these years.
On the right is a diagram of a vertical set up found on [1]. This design doesn't seem to allow for positioning of the point contact, only the overall pressure - which to be fair is generally more important.
Historical variants found on ebay listings
Ebay is a good resource for images of different variants of cat's whisker apparatus. This is the galena point contact diode described in Semiconductor history and is a typical form found in (usually I think) British made crystal radios.
It's a horizontal setup and protects the crystal with a glass envelope. You can clearly see a direct link to modern components like this germanium diode, which still uses the point contact idea - but is fixed and much smaller:
This is another variant of the horizontal construction, there were probably as many varieties of these as there were companies manufacturing radios (several hundred) including home made designs.
The other common approach was to mount the crystal at right angles to the 'arm' and allow it to be adjusted in a similar way, but pointing down on the crystal. These tend not to be enclosed in glass, and seem (as far as I can tell) to be slightly more common in the USA.
Multi crystal sets
Many radios feature multiple crystals and a switch to select which one to use. This is presumably an indication of their unreliability and drift over time - something I have also experienced in use in audio circuits. You could use one for a bit and then switch to the other, perhaps for different frequencies - although I feel the advantages may have been more imagined if they were using galena for both. Given that the mechanism causing semiconducting were not understood at the time, this may have been understandable.
This is a piece of equipment specifically for testing crystals. It's unclear but possibly the one on the left is for testing two crystals brought into contact with each other. "Perikon" was the name given to combining chalcopyrite and zincite, which was made in this way.
Sometimes different types of crystal could be switched between in a radio. This Marconi Marconiphone "Crystal A" type RB3 radio set from 1922, which seems so different in it's construction methods to those of today it almost invites a comparison to be drawn to quantum computing technology. It has two rectifier options: galena, as we have seen already - and carborundum (silicon carbide), which is very rare in nature but is created via industrial processes for many uses due to its relative hardness.
Instead of a cat's whisker, the carborundum is fashioned into a point that makes contact with a metal plate - so the inverse of the galena point contact. The contact pressure can be adjusted with a thumb screw - this image show the parts disassembled. It seems a common feature of these devices to be easily
