Apparatus, methods and systems for measuring and detecting electrical discharge

The invention claimed is: 1. An apparatus for detecting and measuring an electrical discharge having a discharge magnitude, wherein the electrical discharge causes a corresponding emission of optical radiation, wherein the apparatus comprises: an optical receiver arrangement configured to receive optical radiation from a scene comprising a source of a potential electrical discharge; a first image forming means configured to form an image based on the optical radiation received by the optical receiver arrangement; a measurement system, wherein the measurement system comprises: an optical detector optically coupled to the optical receiver arrangement to receive and process the optical radiation from the optical receiver arrangement to generate a detector output; a memory device storing pre-determined calibration data comprising calibrated quantitative measurement values associated with magnitudes of electrical discharge and detector parameters corresponding thereto, the detector parameters being operating parameters associated with the optical detector; and a quantitative measurement module configured to receive and process a particular detector parameter with the stored calibration data thereby to detect an electrical discharge, and determine a quantitative measurement associated with the magnitude of the detected electrical discharge; a display device for displaying images formed by the first image forming means; and an image processor configured to overlay the determined quantitative measurement onto the image displayed by the display device. 2. An apparatus as claimed in claim 1 , wherein the quantitative measurement module is configured to process the received detector parameter with the stored calibration data by: comparing the received detector parameter with detector parameters forming part of the calibration data; retrieving, upon a match, a calibrated quantitative measurement value corresponding to the matching detector parameter, wherein a match results in a detection of an electrical discharge, and optionally use the retrieved calibrated quantitative measurement value to determine the quantitative measurement associated with the magnitude of the detected electrical discharge. 3. An apparatus as claimed in claim 1 , wherein the apparatus is in the form of a portable camera comprising a power supply; portable housing defining at least one optical aperture such that optical radiation emanating from outside the portable housing enters the housing, wherein the housing encloses the components of the apparatus; and at least one eye piece visually alignable with the display device to permit viewing of the same. 4. An apparatus as claimed in claim 1 , wherein the optical receiver arrangement comprises: a light-collector comprising one or more optical lenses and/or filters to receive optical radiation; and a beam splitter optically coupled to the light-collector and configured to reflect all or part of the spectrum of the received optical radiation to the first image forming means and to the measurement system. 5. An apparatus as claimed in claim 1 , wherein the apparatus is calibrated to a calibration source of optical radiation, the calibrated quantitative measurement values being one or more of temperature, irradiance, and power associated with the calibration source; and wherein the detector parameters forming part of the calibration data correspond to the calibrated quantitative measurement values. 6. An apparatus as claimed in claim 1 , wherein the optical detector comprises a photocathode operable to convert photons from the received optical radiation to photo-electrons, a multiplier means coupled to the photocathode operable to apply a gain to the photo-electrons to amplify the same; and an anode configured to convert the amplified electrons to output photons as the detector output. 7. An apparatus as claimed in claim 6 , wherein the apparatus comprises a second image forming means operatively connected to the anode of the optical detector to form an image of the photons output thereby, wherein the image processing means is configured to overlay the image formed by the second image forming means onto the image formed by the first image forming means. 8. An apparatus as claimed in claim 6 , wherein the measurement system comprises a current measuring module configured to determine an electrical parameter associated with one of the photocathode and the anode in processing received optical radiation to output photons, and wherein the particular detector parameter received by the quantitative measurement module is the determined electrical parameter. 9. An apparatus as claimed in claim 8 , wherein the electrical parameter is anode current drawn by the anode of the optical detector in processing the received optical radiation to generate the detector output such that the calibration data comprises a plurality of anode current values and corresponding calibrated quantitative measurement values associated with magnitudes of electrical discharges. 10. An apparatus as claimed in claim 6 , wherein the memory device stores a pre-determined calibration set point associated with the detector output and/or an electrical parameter associated with one of the photocathode and the anode in processing received optical radiation to generate the detector output, wherein the measurement system comprises: a parameter monitoring module configured to receive information indicative of the detector output and/or the electrical parameter to determine variations of the same from the respective calibration set point; and a gain controller module configured to correct or adjust a detector parameter of the optical detector to a corrected detection parameter in response to determining variation of the received detector output and/or electrical parameter from the respective calibration set point so as to maintain a predetermined relationship between detector output and/or electrical parameter and the corresponding calibration set point/s, wherein the particular detector parameter receivable for processing by the quantitative measurement module is the corrected detection parameter, and wherein the calibration data comprises detector parameters and corresponding calibrated quantitative measurement values associated with magnitudes of electrical discharges at which the predetermined relationship between the detector output and/or the electrical parameter and the corresponding calibration set point/s is maintained. 11. A method of measuring an electrical discharge having a discharge magnitude, wherein the electrical discharge causes a corresponding emission of optical radiation, wherein the method comprises: storing, in a memory device, a pre-determined calibration set point for a detector output and/or an electrical parameter associated with an optical detector, wherein the electrical parameter is associated with the operation of the optical detector; storing in the memory device, pre-determined calibration data comprising calibrated quantitative measurement values associated with magnitudes of electrical discharges and corresponding detector parameters associated with operation of the optical detector, wherein the detector parameters forming part of the calibration data are selected to maintain the detector output and/or electrical parameter at the pre-determined calibration set point; receiving information indicative of a monitored detector output and/or electrical parameter, determining variations of the monitored detector output and/or electrical parameter relative to the associated predetermined calibration set point stored in the memory device in response to exposure of the optical detector to the emission of