Magnetomotive force: Difference between revisions

In physics, the magnetomotive force is a quantity appearing in the equation for the magnetic flux in a magnetic circuit, often called Ohm's law for magnetic circuits.^[1] It is the property of certain substances or phenomena that give rise to magnetic fields:

${\displaystyle {\mathcal {F}}=\Phi {\mathcal {R}},}$

where Φ is the magnetic flux and R is the reluctance of the circuit. It can be seen that the magnetomotive force plays a role in this equation analogous to the voltage V in Ohm's law: V = IR, since it is the cause of magnetic flux in a magnetic circuit:^[2]

1. ℱ = NI

   where N is the number of turns in the coil and I is the electric current through the circuit. Sometimes the unit of gilbert is used to express ℱ.

2. ℱ = ΦR

   where Φ is the magnetic flux and R is the magnetic reluctance

3. ℱ = HL

   where H is the magnetizing force (the strength of the magnetizing field) and L is the mean length of a solenoid or the circumference of a toroid

History

The term magnetomotive force was coined by Henry Augustus Rowland in 1880. Rowland intended this to indicate a direct analogy with electromotive force.^[3] The idea of a magnetic analogy to electromotive force can be found much earlier in the work of Michael Faraday (1791-1867) and it is hinted at by James Clerk Maxwell (1831-1879). However, Rowland coined the term and was the first to make explicit an Ohm's law for magnetic circuits in 1873.^[4]

Ohm's law for magnetic circuits is sometimes referred to as Hopkinson's law rather than Rowland's law as some authors attribute the law to John Hopkinson instead of Rowland.^[5] According to a review of magnetic circuit analysis methods this is an incorrect attribution originating from an 1885 paper by Hopkinson.^[6] Furthermore, Hopkinson actually cites Rowland's 1873 paper in this work.^[7]

References

1. Waygood, p. 137
2. Smith, pp. 495-506
3. • Hon & Goldstein, pp. 638-639
   • Rowland (1880), pp. 92, 97
4. • Thompson, p. viii
   • Rowland (1873), p. 143
5. • See for instance
   • Schmidt & Schitter, p. 340, or
   • Waygood, p. 137
6. Lambert et al., p. 2427
7. Hopkinson, p. 455

Bibliography

Cited sources

• Hon, Giora; Goldstein, Bernard R, "Symmetry and asymmetry in electrodynamics from Rowland to Einstein", Studies in History and Philosophy of Modern Physics, vol. 37, iss. 4, pp. 635-660, Elsevier December 2006.
• Hopkinson, John, "Magnetisation of iron", Philosophical Transactions of the Royal Society, vol. 176, pp. 455-469, 1885.
• Lambert, Mathieu; Mahseredjian, Jean; Martínez-Duró, Manuel; Sirois, Frédéric, "Magnetic circuits within electric circuits: critical review of existing methods and new mutator implementations", IEEE Transactions on Power Delivery, vol. 30, iss. 6, pp. 2427-2434, December 2015.
• Rowland, Henry A, "On magnetic permeability and the maximum magnetism of iron, steel, and nickel", Philosophical Magazine, series 4, vol. 46, no. 304, pp. 140-159, August 1873.
• Rowland, Henry A, "On the general equations of electro-magnetic action, with application to a new theory of magnetic attractions, and to the theory of the magnetic rotation of the plane of polarization of light" (part 2), American Journal of Mathematics, vol. 3, nos. 1-2, pp. 89–113, March 1880.
• Schmidt, Robert Munnig; Schitter, Georg, "Electromechanical actuators", ch. 5 in Schmidt, Robert Munnig; Schitter, Georg; Rankers, Adrian; van Eijk, Jan, The Design of High Performance Mechatronics, IOS Press, 2014 ISBN 1614993688.
• Thompson, Silvanus Phillips, The Electromagnet and Electromagnetic Mechanism, Cambridge University Press, 2011 (first published 1891) ISBN 1108029213.
• Smith, R.J. (1966), Circuits, Devices and Systems, Chapter 15, Wiley International Edition, New York. Library of Congress Catalog Card No. 66-17612
• Waygood, Adrian, An Introduction to Electrical Science, Routledge, 2013 ISBN 1135071136.

General references

• The Penguin Dictionary of Physics, 1977, ISBN 0-14-051071-0
• A Textbook of Electrical Technology, 2008, ISBN 81-219-2440-5