Electrochemical device monitoring

1 . A system comprising: an electrochemical device generating a magnetic field; and a sensing device comprising: a magneto-optical medium; an electromagnetic radiation source configured to emit polarized electromagnetic radiation through the magneto-optical medium; and a sensor configured to receive polarized electromagnetic radiation which has passed through the magneto-optical medium; wherein the sensing device is arranged relative to the electrochemical device such that the magnetic field of the electrochemical device passes through the magneto-optical medium. 2 . The system as claimed in claim 1 , where the magneto-optical medium is positioned such that the magnetic field of the electrochemical device interacts with the magneto-optical medium to rotate a polarization plane of the polarized electromagnetic radiation based on a characteristic of the electrochemical device. 3 . The system as claimed in claim 1 or 2 , wherein the electromagnetic radiation source is arranged relative to the electrochemical device such that the emitted polarized electromagnetic radiation is parallel to the generated magnetic field of the electrochemical device. 4 . The system as claimed in any preceding claim , wherein the magneto-optical medium is integral with the electromagnetic radiation source; or wherein the magneto-optical medium is a layer coupled to the electrochemical device. 5 . The system as claimed in any preceding claim , wherein the magneto-optical medium comprises thin film magneto-optical crystals. 6 . The system as claimed in claim 5 , wherein the sensing device further comprises a protective layer of an insulating polymer or glass film for protecting the thin film magneto-optical crystals; or wherein the magneto-optical crystals are embedded with a polymer or glass fibre for protecting the thin film magneto-optical crystals. 7 . The system as claimed in any proceeding claim, wherein the magneto-optical crystals have a high Verdet constant or low optical adsorption; or wherein the magneto-optical crystals comprise at least one of barium hexaferrites, terbium gallium garnet, bismuth doped rare earth iron garnet, Na 2 Ce(MoO 4 ) 2 or CeAlO 3 . 8 . The system as claimed in any preceding claim , wherein the electrochemical device generating a magnetic field is a battery comprising a plurality of cells; wherein the system comprises a plurality of electromagnetic radiation sources, each associated with one of the plurality of cells; and wherein the system further comprises a plurality of magneto-optical mediums, each associated with one of the plurality of cells. 9 . The system as claimed in claim 8 , wherein the system is configured to operate the plurality of electromagnetic radiation sources in series; and wherein the sensor is configured to receive polarized electromagnetic radiation which has passed through one of the plurality of magneto-optical mediums from each of the electromagnetic radiation sources. 10 . The system as claimed in claim 8 , wherein the system further comprises a plurality of sensors associated with the plurality of electromagnetic radiation sources. 11 . The system as claimed in any preceding claim , wherein the system comprises a control module configured to: determine a first polarization plane of the emitted electromagnetic radiation, or store a predetermined polarization plane of the emitted electromagnetic radiation; determine a second polarization plane of the electromagnetic radiation which has passed through the magneto-optical medium; determine an angle of rotation between the first and second polarization planes; determine a magnetic field strength of the electrochemical device based on the determined angle of rotation; and determine the current distribution of the electrochemical device based on the determined magnetic field. 12 . A method of sensing comprising: providing the system of any preceding claim ; emitting, from the electromagnetic radiation source, a polarized electromagnetic radiation through the magneto-optical medium; receiving, with the sensor, the polarized electromagnetic radiation which has passed through the magneto-optical medium. 13 . The method as claimed in claim 12 , wherein the method further comprises: determining an angle of rotation of a polarization plane of the reflected electromagnetic radiation. 14 . The method as claimed in claim 13 , wherein the method further comprises: determining the magnetic field strength an electrochemical device based on the determined angle of rotation; and determining the current distribution of the electrochemical device based on the determined magnetic field. 15 . The method as claimed in claim 14 , further comprising repeating the determination of the current distribution of the electrochemical device periodically or for a plurality of positions upon the electrochemical device; and determining a temporal or spatial variation in current distribution information of the electrochemical device. 16 . The method as claimed in claim 15 , wherein emitting the polarized electromagnetic radiation to a magneto-optical medium comprises emitting the electromagnetic radiation from a plurality of fibre optic cables. 17 . The method as claimed in claim 16 , wherein the electromagnetic radiation is emitted from the plurality of fibre optic cables independently over the time period such that the electromagnetic radiation is incident on the magneto-optical medium in a pattern or series. 18 . The method as claimed in claim 16 wherein the electromagnetic radiation is emitted from the plurality of fibre optic cables simultaneously and the plurality of fibre optic cables are configured to emit a different wavelength of electromagnetic radiation to an adjacent fibre optic cable. 19 . The method as claimed in any one of claim 15 to claim 18 , wherein the system comprises a control module configured to receive the variation in current distribution information; and wherein the control module is configured to change a parameter of the electrochemical device based on the variation in current distribution information; or wherein the control module is configured to trigger an alarm based on the variation in current distribution information. 20 . A sensing device comprising: a magneto-optical medium; an electromagnetic radiation source configured to emit polarized electromagnetic radiation through the magneto-optical medium; and a sensor configured to receive polarized electromagnetic radiation reflected from the electromagnetic radiation source through the magneto-optical medium, wherein the electromagnetic radiation source comprises a first plurality of fibre optic cables, or wherein the sensor comprises a second plurality of fibre optic cables. 21 . A sensing device as claimed in claim 18 , further comprising at least one of a reflective layer or a protective medium. 22 . The sensing device of claim 18 , wherein the first plurality of fibre optic cables and the second plurality of fibre optic cables are arranged in a mesh or woven array. 23 . The sensing device of claim 20 , wherein at least one of the first or second plurality of fibre optic cables is configured to be embedded inside the electrochemical device. 24 . The sensing device of any one of claims 20 to 21 , wherein the first plurality of fibre optic cables are configured to emit electromagnetic radiation independently over a period of