The Wiegand effect is a nonlinear magnetic effect, named after its discoverer

John R. Wiegand John Richard Wiegand (February 23, 1912 - December 1986)Bru ...

, produced in specially annealed and hardened

wire Overhead power cabling. The conductor consists of seven strands of steel (centre, high tensile strength), surrounded by four outer layers of aluminium (high conductivity). Sample diameter 40 mm A wire is a flexible strand of metal. Wire is co ...

called Wiegand wire. Wiegand effect

Wiegand wire is low-carbon Vicalloy, a

ferromagnetic Ferromagnetism is a property of certain materials (such as iron) which results in a large observed magnetic permeability, and in many cases a large magnetic coercivity allowing the material to form a permanent magnet. Ferromagnetic materials ...

alloy An alloy is a mixture of chemical elements of which at least one is a metal. Unlike chemical compounds with metallic bases, an alloy will retain all the properties of a metal in the resulting material, such as electrical conductivity, ductili ...

cobalt Cobalt is a chemical element with the symbol Co and atomic number 27. As with nickel, cobalt is found in the Earth's crust only in a chemically combined form, save for small deposits found in alloys of natural meteoric iron. The free element, p ...

iron Iron () is a chemical element with symbol Fe (from la, ferrum) and atomic number 26. It is a metal that belongs to the first transition series and group 8 of the periodic table. It is, by mass, the most common element on Earth, right in ...

, and

vanadium Vanadium is a chemical element with the symbol V and atomic number 23. It is a hard, silvery-grey, malleable transition metal. The elemental metal is rarely found in nature, but once isolated artificially, the formation of an oxide layer ( pass ...

. Initially, the wire is fully annealed. In this state the alloy is "soft" in the magnetic sense; that is, it is attracted to magnets and so magnetic field lines will divert preferentially into the metal, but the metal retains only a very small residual field when the external field is removed. During manufacture, to give the wire its unique magnetic properties, it is subjected to a series of twisting and untwisting operations to cold-work the outside shell of the wire while retaining a soft core within the wire, and then the wire is aged. The result is that the magnetic

coercivity Coercivity, also called the magnetic coercivity, coercive field or coercive force, is a measure of the ability of a ferromagnetic material to withstand an external magnetic field without becoming demagnetized. Coercivity is usually measured in ...

of the outside shell is much larger than that of the inner core. This high coercivity outer shell will retain an external magnetic field even when the field's original source is removed. The wire now exhibits a very large

magnetic hysteresis Magnetic hysteresis occurs when an external magnetic field is applied to a ferromagnet such as iron and the atomic dipoles align themselves with it. Even when the field is removed, part of the alignment will be retained: the material has become '' ...

: If a magnet is brought near the wire, the high coercivity outer shell excludes the magnetic field from the inner soft core until the magnetic threshold is reached, whereupon the entire wire — both the outer shell and inner core — rapidly switches magnetisation polarity. This switchover occurs in a few microseconds, and is called the Wiegand effect. The value of the Wiegand effect is that the switchover speed is sufficiently fast that a significant voltage can be output from a coil using a Wiegand-wire core. Because the voltage induced by a changing magnetic field is proportional to the rate of change of the field, a Wiegand-wire core can increase the output voltage of a magnetic field sensor by several orders of magnitude as compared to a similar coil with a non-Wiegand core. This higher voltage can easily be detected electronically, and when combined with the high repeatability threshold of the magnetic field switching, making the Wiegand effect useful for positional sensors. Once the Wiegand wire has flipped magnetization, it will retain that magnetization until flipped in the other direction. Sensors and mechanisms that use the Wiegand effect must take this retention into account. The Wiegand effect is a macroscopic extension of the Barkhausen effect, as the special treatment of the Wiegand wire causes the wire to act macroscopically as a single large magnetic domain. The numerous small high-coercivity domains in the Wiegand wire outer shell switch in an avalanche, generating the Wiegand effect's rapid magnetic field change.

Applications

Wiegand Sensors

Wiegand sensors are magnetic sensors that make use of the Wiegand effect to generate a consistent pulse every time

magnetic field A magnetic field is a vector field that describes the magnetic influence on moving electric charges, electric currents, and magnetic materials. A moving charge in a magnetic field experiences a force perpendicular to its own velocity and to ...

polarity reverses and therefore do not rely on any external voltage or current. The consistency of the pulses produced by Wiegand sensors can be used to provide energy for low-power and energy-saving applications. Being self-powered, Wiegand sensors have a potential in IoT applications as energy harvesters, proximity sensors, and event counters.

Wiegand keycards

Besides sensors, the Wiegand effect is used for security keycard door locks. The plastic keycard has a series of short lengths of Wiegand wire embedded in it, which encodes the key by the presence or absence of wires. A second track of wires provides a

clock A clock or a timepiece is a device used to measure and indicate time. The clock is one of the oldest human inventions, meeting the need to measure intervals of time shorter than the natural units such as the day, the lunar month and ...

track. The card is read by pulling it through a slot in a reader device, which has a fixed magnetic field and a sensor coil. As each length of wire passes through the magnetic field, its magnetic state flips, which indicates a 1, and this is sensed by the coil. The absence of a wire indicates a 0. The resulting Wiegand protocol digital code is then sent to a host controller to determine whether to electrically unlock the door. Wiegand cards are more durable and difficult to counterfeit than bar code or magnetic stripe cards. Since the keycode is permanently set into the card at manufacture by the positions of the wires, Wiegand cards can't be erased by magnetic fields or reprogrammed as magnetic stripe cards can.

Rotary encoder

Wiegand wires are used by some rotary magnetic encoders to power the multi-turn circuitry. As the encoder revolves, the Wiegand wire core coil generates a pulse of electricity sufficient to power the encoder and write the turns count to non-volatile memory. This works at any speed of rotation and eliminates the clock/gear mechanism typically associated with multi-turn encoders.

Wheel speed sensor

Wiegand wires are fitted to the outer diameter of a wheel to measure rotational speeds. An externally mounted reading head detects the Wiegand pulses.

References

External links

* — The original Wiegand patent (1974) * — The patent on Vicalloy

— An explanation of the Wiegand effect as used in access control * {{cite web, last1=Wehr, first1=John, title=The Wiegand Effect: The 30-year old science project still influences modern security systems, url=https://www.secureidnews.com/news-item/the-weigand-effect-the-30-year-old-science-project-still-influences-modern-security-systems/, website=SecureIDNews, archive-url=https://web.archive.org/web/20180412142831/https://www.secureidnews.com/news-item/the-weigand-effect-the-30-year-old-science-project-still-influences-modern-security-systems/, archive-date=2018-04-12, date=September 1, 2003