Electromagnetic device

The invention claimed is: 1. An electromagnetic device comprising: a core support having an exterior surface comprising at least one radial protrusion; a tubular magnetic core positioned around a portion of the length of the core support, the tubular magnetic core having an interior surface; at least one indent located in the interior surface of the tubular magnetic core, wherein the at least one protrusion is located within the at least one indent to prevent relative longitudinal movement between the core support and tubular magnetic core; and a primary coil and at least one secondary coil, each coil positioned around a portion of a length of the tubular magnetic core; wherein the tubular magnetic core is formed from a rolled or folded sheet material; and wherein the indent has been formed by pressing the interior surface of the tubular magnetic core onto the at least one radial protrusion. 2. The electromagnetic device of claim 1 , wherein the at least one indent and the at least one protrusion have matching or complementary profiles. 3. The electromagnetic device of claim 2 , wherein the at least one protrusion comprises multiple protrusions. 4. The electromagnetic device of claim 1 , wherein the at least one protrusion comprises at least one circumferential ring extending around the core support. 5. The electromagnetic device of claim 4 , wherein the at least one circumferential ring comprises multiple circumferential rings. 6. The electromagnetic device of claim 1 , wherein the at least one protrusion tapers to a tip in a direction away from the exterior surface of the core support. 7. The electromagnetic device of claim 1 , wherein the electromagnetic device is a linear variable differential transducer, and wherein the magnetic core is moveable relative to the primary and secondary coils. 8. The electromagnetic device of claim 7 , comprising said primary coil wound around a first bobbin, a first secondary coil wound around a second bobbin, and a second secondary coil wound around a third bobbin; wherein the first, second, and third bobbins are positioned around a portion of a length of the magnetic core, the first bobbin being located between the second and third bobbins; and wherein there is a gap between first bobbin and at least one of the second or third bobbins. 9. The electromagnetic device of claim 1 , wherein the at least one protrusion located within the at least one indent prevents circumferential movement between the core support and the tubular magnetic core. 10. A method of forming the electromagnetic device that includes: a core support having an exterior surface comprising at least one radial protrusion; a tubular magnetic core positioned around a portion of the length of the core support, the tubular magnetic core having an interior surface; at least one indent located in the interior surface of the tubular magnetic core, wherein the at least one protrusion is located within the at least one indent to prevent relative longitudinal movement between the core support and tubular magnetic core; and a primary coil and at least one secondary coil, each coil positioned around a portion of a length of the tubular magnetic core, wherein the tubular magnetic core is formed from a rolled or folded sheet material, and wherein the indent has been formed by pressing the interior surface of the tubular magnetic core onto the at least one radial protrusion, the method comprising: providing the core support; and rolling or folding a sheet of magnetisable material around the core support so as to form the tubular magnetic core, wherein the rolling or folding is performed such that the at least one protrusion on the core support penetrates the sheet of magnetisable material to form the at least one indent in the tubular magnetic core. 11. The method of claim 10 , wherein the sheet of magnetisable material is more ductile or more soft than the core support, and the method further comprises pressing the sheet of magnetisable material against the core support such that the at least one protrusion will press into the tubular magnetic core to form the at least one indent without the at least one protrusion substantially deforming. 12. A linear variable differential transducer comprising: a magnetic core; a primary coil wound around a first bobbin; a first secondary coil wound around a second bobbin; and a second secondary coil wound around a third bobbin; wherein the first, second, and third bobbins are positioned around a portion of a length of the magnetic core, the first bobbin being located between the second and third bobbins; and wherein there is a gap between first bobbin and at least one of the second or third bobbins. 13. The linear variable differential transducer of claim 12 , wherein the first, second and third bobbins are fixedly attached to a support. 14. The linear variable differential transducer of claim 12 , further comprising a core support having an exterior surface comprising at least one radial protrusion, wherein the magnetic core is a tubular magnetic core positioned around a portion of a length of a core support, and wherein the at least one protrusion is located within at least one indent in an interior surface of the tubular magnetic core to prevent relative longitudinal movement between the core support and tubular magnetic core. 15. A method for making the linear variable differential transducer of claim 12 , the method comprising: (i) positioning the first, second and third bobbins around a portion of a length of the magnetic core; (ii) adjusting the positions of the first, second, and third bobbins relative to each other; and (iii) after (ii), fixing the positions of first, second and third bobbins relative to each other. 16. The method of claim 15 , comprising: connecting the primary coil to a voltage supply; monitoring an electrical response at the first and second secondary coils; performing said step of adjusting the positions of the first, second, and third bobbins relative to each other until the bobbins are at positions in which the electrical response at the first and second secondary coils is a desired or predetermined response; and then fixing the first, second and third bobbins relative to each other in these positions.