A membrane keyboard is a computer keyboard whose "keys" are not separate, moving parts, as with the majority of other keyboards, but rather are pressure pads that have only outlines and symbols printed on a flat, flexible surface. Very little, if any, tactile feedback is felt when using such a keyboard, and error-free blind typing is difficult.
Membrane keyboards work by electrical contact between the keyboard surface and the underlying circuits when keytop areas are pressed. These models were used with some early 1980s home computers, enjoying wide adoption in consumer electronics devices. The keyboards are quite inexpensive to mass-produce, and are more resistant against dirt and liquids than most other keyboards. However, due to a low or non-existent tactile feedback, most people have difficulty typing with them, especially when larger numbers of characters are being typed. Chiclet keyboards were a slight improvement, at least allowing individual keys to be felt to some extent.
Aside from early hobbyist/kit/home computers and some video game consoles, membrane-based QWERTY keyboards are used in some industrial computer systems, and are also found as portable, even "rollable-collapsible" designs for PDAs and other pocket computing devices. Smaller, specialised membrane keyboards, typically numeric-and-a-few-control-keys only, have been used in access control systems (for buildings and restricted areas), simple handheld calculators, domestic remote control keypads, microwave ovens, and other similar devices where the amount of typing is relatively small or infrequent, such as cell phones.
Modern PC keyboards are essentially a membrane keyboard mechanism covered with an array of dome switches which give positive tactile feedback.
Video Membrane keyboard
How it works
As can be seen from the diagram below, the membrane keyboard basically consists of three layers; two of these are membrane layers containing conductive traces. The center layer is a "spacer" containing holes wherever a "key" exists. It keeps the other two layers apart.
Under normal conditions, the switch (key) is open, because current cannot cross the non-conductive gap between the traces on the bottom layer. However, when the top layer is pressed down (with a finger), it makes contact with the bottom layer. The conductive traces on the underside of the top layer can then bridge the gap, allowing current to flow. The switch is now "closed", and the parent device registers a keypress.
Typical applications include;
- Industrial controls
- Access control systems
- Medical equipment
- Telecommunications apparatus
- Telephone systems
- Household appliances
- Security systems
- Office use
Source, APEM, Membrane switch panels
Maps Membrane keyboard
List of keyboards with membrane interfaces
QWERTY layouts unless otherwise specified
- Atari 400 (full-travel replacement keyboards much like those that came with the Atari 800 were available)
- Cambridge Z88 (arguably a mix between a membrane and chiclet keyboard)
- Elektronika BK-0010, in early versions (it was a Russian home computer, hence the JCUKEN layout)
- Magnavox Odyssey², also known as the Philips Videopac G7000 video game console
- RCA COSMAC VIP, a do-it-yourself (DIY) kit computer with 16-key hex keypad
- Robotron Z1013, Eastern-German home computer (alphabetical layout)
- SEGA SC-3000, a computer version of an early SEGA game console
- Science of Cambridge Microcomputer Kit 14 (MK14); the initial version had a 20-key extended hex keypad
- Sinclair ZX80, a pioneering British home computer that was available as a DIY kit
- Sinclair ZX81 (similar to the preceding entry)
- Speak & Spell (ABC layout until 1989)
- Synertek SYM-1, a sibling of the MOS/CBM KIM-1 with a 29-key extended hex keypad
- Timex Sinclair 1000 (a U.S. version of the ZX81)
See also
- Chiclet keyboard
- Keyboard technology
References
External links
- Structure of Membrane Keyboards
Source of the article : Wikipedia