Calibration method of plurality of scanners in an additive manufacturing apparatus

The invention claimed is: 1. A method for determining a correction of beam steering optics of a scanner of an additive manufacturing apparatus comprising a plurality of scanners, each scanner of the plurality of scanners comprising beam steering optics for directing a corresponding radiation beam to a working plane in which a material is consolidated in layers, the method comprising controlling the beam steering optics of a pair of the scanners such that a first scanner of the pair directs a radiation beam to form a feature in the working plane and the feature is within a field of view of a detector of a second scanner of the pair, the detector for detecting radiation coming from the working plane that is collected by the beam steering optics of the second scanner, recording at least one detector value with the detector of the second scanner when the feature falls within the field of view, and determining a correction value for correcting for misalignment in positioning of the radiation beams by the beam steering optics of the first and second scanners from a comparison of a position of the feature in the field of view derived from the at least one detector value with an expected detector position value, the expected position value determined from a positioning of the steering optics of the first scanner of the pair when forming the feature and a positioning of the steering optics of the second scanner of the pair when the at least one detector value is recorded. 2. The method according to claim 1 , wherein the feature is a melt pool formed in the working plane by the radiation beam of the first scanner of the pair. 3. A method for determining a correction of beam steering optics of a scanner of an additive manufacturing apparatus comprising a plurality of scanners, each scanner comprising beam steering optics for directing a corresponding radiation beam to a working plane in which a material is consolidated in layers and a detector for detecting radiation coming from the working plane that is collected by the beam steering optics, the method comprising controlling the beam steering optics of first and second scanners of a pair of the scanners such that fields of view of the working plane for the detectors of the first and second scanners at least overlap, recording at least one detector value with the detector of each of the first and second scanners for the corresponding field of view, and determining a correction value for correcting for misalignment in positioning of the radiation beams by the beam steering optics of the first and second scanners from a comparison of positions of a feature in the fields of view derived from the detector values recorded by the first and second scanners and a positioning of the steering optics of the first and second scanners when the detector values are recorded. 4. The method according to claim 3 , wherein the fields of view are nominally coterminous when the detector values are recorded. 5. The method according to claim 3 , comprising recording the detector values when a radiation beam is directed onto the material in the working plane within the fields of view by one of the plurality of scanners. 6. The method according to claim 3 , comprising recording the detector values based upon the feature within the fields of view formed using one of the radiation beams. 7. The method according to claim 3 , comprising recording the detector values based upon a reference pattern located within the fields of view. 8. The method according to claim 7 , wherein the reference pattern is one selected from: i) formed using one of the radiation beams; ii) formed in the working plane using one of the radiation beams by ablating a surface in the working plane or consolidating the material in the working plane; and iii) preformed on a reference artefact that is placed in the additive manufacturing apparatus such that the reference pattern is in the fields of view. 9. The method according to claim 7 , wherein, the reference pattern comprises at least one periodic feature, the method comprising capturing an image of the reference pattern with the detector of the second scanner, determining from the image a measured periodic property of the reference pattern and determining a correction for control of the first or second scanner based upon a comparison of the measured periodic property with a reference periodic property. 10. The method according to claim 9 , wherein the reference periodic property is determined from instructions used to drive the first scanner when forming the reference pattern or a further image of the reference pattern captured by the detector of the first scanner. 11. The method according to claim 3 , wherein the correction value is determined by cross-referencing data, including the detector value(s), from the first and second scanners. 12. The method according to claim 11 , wherein the correction value is determined from a difference in a measured position of: a spot of at least one of the radiation beams or the feature formed by at least one of the radiation beams within the field of view from a nominal value. 13. The method according to claim 1 , comprising adjusting the additive manufacturing apparatus to correct for the misalignment in the positioning of the radiation beams by the beam steering optics of the first and second scanners. 14. The method according to claim 1 , wherein the additive manufacturing apparatus comprises more than two scanners and the method is carried out for multiple pairs of the more than two scanners to generate correction values, maps or functions that correct at least one position of the steering optics of one of the scanners of each pair such that the more than two scanners are aligned to a common frame of reference. 15. The method according to claim 3 , wherein the additive manufacturing apparatus comprises more than two scanners and the method is carried out for multiple pairs of the more than two scanners to generate correction values, maps or functions that correct at least one position of the steering optics of one of the scanners of each pair such that the more than two scanners are aligned to a common frame of reference. 16. An additive manufacturing apparatus for building up a workpiece in a layer-by-layer manner comprising a plurality of scanners, each scanner for directing a radiation beam to consolidate a material in a working plane in layers and a controller arranged to carry out the method of claim 1 . 17. An additive manufacturing apparatus for building up a workpiece in a layer-by-layer manner comprising a plurality of scanners, each scanner for directing a radiation beam to consolidate a material in a working plane in layers and a controller arranged to carry out the method of claim 3 . 18. A non-transitory computer readable medium having instructions thereon, which, when executed by a controller for controlling an additive manufacturing apparatus, cause the controller to carry out the method of claim 1 . 19. A non-transitory computer readable medium having instructions thereon, which, when executed by a controller for controlling an additive manufacturing apparatus, cause the controller to carry out the method of claim 3 . 20. A method for determining a correction of beam steering optics of a scanner of an additive manufacturing apparatus comprising a plurality of scanners, each scanner comprising beam steering optics for directing a corresponding radiation beam to a working plane in which a material is consolidated in layer