Electrical and Electronic Principles

1. Electrical and Electronic Principles BTEC National Diploma O Introduction

2. Magnetism Assessment Criteria P7. describe the characteristics of a magnetic field. P8. describe the relationship between flux density (B) & field strength (H). P9. describe the principles & applications of electromagnetic induction. D1. analyse the operation and the effects of varying component parameters of a power supply circuit that includes a transformer, diodes and capacitors.

3. Know the principles and properties of magnetism: content Magnetic field: Electromagnetic induction: Principles eg induced electromotive force (emf), eddy currents, self and mutual inductance; Applications (electric motor/generator eg series and shunt motor/generator; transformer eg primary and secondary current and voltage ratios); Application of Faraday’s and Lenz’s laws • Magnetic field patterns eg flux, flux density (B), magnetomotive force (mmf) and field strength (H), permeability, B/H curves and loops; • Ferromagnetic materials; reluctance; magnetic screening; hysteresis

4. Magnetic fields throughout the Universe THE COMA CONSTELLATION Pretty much each dot here is a galaxy • Almost all white blobs on the left hand optical image of the constellation Coma are – not stars – but whole galaxies (each of which contains billions of stars). • The radio image on the right of the same part of space gives an indication of the distribution of the magnetic fields in the regions of space between the galaxies. Images: (1) ESO; (2) H. Lesch, USM

5. Magnetars have the STRONGEST magnetic fields in the Universe About one tenth of neutron stars are magnetars. Their magnetic fields are a hundred million times greater than the of the strongest man-made magnet (a neodymium-based, rare-earth magnet has a field of about 1 tesla). Weird things happen in these immense magnetic fields. For example, a hydrogen atom deforms into a spindle 200 times narrower than its normal diameter. The interior field of SGR 0418+5729 (above) is about a trillion (1012) tesla, one of the strongest magnetic fields in the known Universe – here shown bursting of the star’s surface in the form of a loop. (Image: ESA/ATGMedialab)

6. The magnetic fields of our galaxy, the Milky Way • The main magnetic field structure lies in the plane of the disc and follows the spiral arms. • The red arrows are in the opposite direction to the black ones – i.e. the magnetic field is reversed. • There is also a toroidal and a poloidal magnetic field (not shown)

7. The Sun’s magnetic field lines.[August 2010] The dark areas are coronal holes from which lots of field lines whip out into space. The corona is the outmost layer of the sun. Image: NASA SDO/Lockheed Martin Space Systems Company

8. The heliosphere is not exactly a sphere!

9. Part of the heliosphere: more detail

10. Solar System cutting through Milky Way’s magnetic field This graphic depicts the Solar System, encased in a bullet-shaped envelope of charged particles (yellow), as it streaks through the interstellar magnetic field of the Milky Way galaxy (brown lines) at about 62,000 miles an hour.Image courtesy Opher et al., 2007/Science

11. The Earth’s magnetic fieldhas been weakening over the past 180 years or so Close up, the fieldlooks like thatof a bar magnet

12. The Earth’s internal structure Moon-sized SOLID iron-nickel inner core superrotating eastwards. MOLTEN iron-nickel outer core rotating westwards. Moving charged particles such as eg free electrons instigate the magnetic field.

13. Earth’s magnetic field viewed from further out As it orbits the Sun, the Earth’s magnetic field DISTORTS as it ‘pushes against’ the Sun’s solar wind (which follows the direction of the Sun’s own magnetic field).

14. Magnetic ores A lodestoneis a naturally magnetized piece of magnetite. It is by far the most magnetic of all minerals. Lodestones – from the Saxon loeden,“meaning leading or directing - were used as the first magnetic compasses. The name magnetmay come from lodestones found in the ancient Greek city of Magnesia. Lodestone at the Smithsonian Institute

15. Animal magnetism ‘Magnetotactic’ bacteria orient themselves and move along Earth’s magnetic field lines. Theories as to how birds such as pigeons navigate using the Earth’s magnetic field refer to inbuilt compasses in the ears, the eyes, the beak or the brain.

16. The cosmological origin of electromagnetism • According to theory, immediately after the Big Bang, there was only one super-force. • This super-force split in stages into four separate fundamental forces (interactions). • Electromagnetism is one of these four, the other three being gravitation, the strong nuclear interaction and the weak nuclear interaction. • Electromagnetism includes both electricity and magnetism as elements of one phenomenon. Electricity and magnetism are linked.

17. Greek alphabet

18. Roman numerals 1 – I ori2 – II orii3 – III oriii4 – IV oriv5 – V orv6 – VI orvi7 – VII orvii 8 – VIII orviii9 – IX orix10 – X orx11 – XI orxi12 – XII orxii13 – XIII orxiii14 – XIV orxiv15 – XV orxv16 – XVI orxvi17 – XVII orxvii18 – XVIII orxviii19 – XIX orxix 20 – XX orxx • The letters should be arranged from the one with the largest value to the one with the smallest. • Each letter's value is added to the previous ones. • Only powers of ten (I, X, C, M) can be repeated. • Do not repeat any letter more than three times in a row. • Because of the preceding rule, certain numbers must be written using subtraction. In this case, a letter with a smaller value precedes one with a larger value and the value of the smaller is subtracted from the larger. The result is then added to the rest of the letters. The following rules apply to subtraction: • Only powers of ten (I, X, C, M) can be subtracted. • The smaller letter must be 1/5th (one-fifth) or 1/10th (one-tenth) the larger one. • The smaller letter must be either the first letter or preceded by a letter at least ten times greater than it. • If another letter follows the larger one, it must be smaller than the number preceding the larger one.

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