Matrix converter control using predicted output current

The invention claimed is: 1. A method of generating a control strategy for a matrix converter, the method comprising: with one or more processors: obtaining a target output transformation result representing a mathematical transformation result of a desired multi-phase output current of the matrix converter; obtaining, for each of a plurality of switching states of the matrix converter, a predicted output transformation result representing a mathematical transformation result of a predicted output current for the switching state; obtaining, for each of the plurality of switching states, a predicted error between the predicted output transformation result associated with the switching state and the target output transformation result; identifying from the plurality of switching states at least three switching states having predicted errors that, when mapped using a Cartesian co-ordinate system, have positions defining an area that contains a zero error position; and generating a control strategy for the matrix converter based on the at least three switching states. 2. The method of claim 1 , wherein the obtaining, for each switching state in the plurality of switching states, the predicted output transformation result comprises obtaining, for each switching state, a predicted output transformation result from a simulated or mathematical model of the matrix converter and a load of the matrix converter. 3. The method of claim 1 , wherein the obtaining, for each switching state in the plurality of switching states, the predicted output transformation result comprises: predicting, using a simulated or mathematical model of the matrix converter and a load of the matrix converter, an output current of the matrix converter associated with each switching state in the plurality of switching states; and performing a mathematical transformation on the predicted output current associated with each switching state to thereby obtain a predicted output transformation result for each switching state in the plurality of switching states. 4. The method of claim 1 , wherein generating the control strategy comprises: calculating a duty cycle for the at least three switching states based on the target output transformation result; and generating the control strategy for the matrix converter based on the calculated duty cycles. 5. The method of claim 1 , wherein the mathematical transformation is an alpha-beta transformation, such that the target output transformation result represents an alpha-beta transformation result of a desired multi-phase output current of the matrix converter and each predicted output transformation result represents an alpha-beta transformation result of a predicted output current for a respective switching state. 6. The method of claim 1 wherein the zero error position corresponds to an origin of the Cartesian co-ordinate system. 7. The method of claim 1 wherein generating the control strategy comprises identifying a linear combination of predicted error vectors corresponding to the at least three switching states that results in zero current error. 8. A method of generating a control strategy for a matrix converter, the method comprising: with one or more processors: obtaining a target output transformation result representing a mathematical transformation result of a desired multi-phase output current of a matrix converter; identifying, based on one or more of output voltage and desired input current, a reduced set of switching states from a set of possible switching states of the matrix converter; obtaining, for each switching state in the reduced set of switching states of the matrix converter, a predicted output transformation result representing a mathematical transformation result of a predicted output current for the switching state; and identifying from the reduced set of switching states at least three switching states having corresponding predicted output transformation results that, when mapped using a Cartesian co-ordinate system, have positions defining an area that contains a position of the target output transformation result, at least one of the at least three switching states corresponding to a zero switching state; and generating a control strategy for the matrix converter based on the at least three switching states. 9. The method of claim 8 , wherein the obtaining, for each switching state in the reduced set of switching states, a predicted output transformation result comprises, obtaining, for each switching state, a predicted output transformation result from a simulated or mathematical model of the matrix converter and a load of the matrix converter. 10. The method of claim 8 , wherein the obtaining, for each switching state in the reduced set of switching states, a predicted output transformation result comprises: predicting, using a simulated or mathematical model of the matrix converter and a load of the matrix converter, an output current of the matrix converter associated with each switching state in the reduced set of switching states; and performing a mathematical transformation on the predicted output current associated with each switching state to thereby obtain a predicted output transformation result for each switching state in the reduced set of switching states. 11. The method of claim 8 wherein the area is defined by a shape having a vertex at a position of a predicted output transformation result corresponding to the zero switching state. 12. The method of claim 8 wherein generating the control strategy comprises identifying a linear combination of vectors corresponding to the at least three switching states that results in a target current vector associated with the target output transformation result. 13. A control strategy generator for a matrix converter, comprising: one or more processors adapted to: obtain a target output transformation result representing a mathematical transformation result of a desired multi-phase output current of the matrix converter; identify, based on one or more of output voltage and desired input current, a reduced set of switching states from a set of possible switching states of the matrix converter; obtain, for each switching state in a reduced set of switching states of the matrix converter, a predicted output transformation result representing a mathematical transformation result of a predicted output current for the switching state; identify from the reduced set of switching states at least three switching states having corresponding predicted output transformation results that, when mapped using a Cartesian co-ordinate system, have positions defining an area that contains a position of the target output transformation result, at least one of the at least three switching states corresponding to a zero switching state; and generate a control strategy for the matrix converter based on the at least three switching states. 14. The control strategy generator of claim 13 wherein the one or more processors are further adapted to obtain, for each switching state, a predicted output transformation result from a simulated or mathematical model of the matrix converter and a load of the matrix converter. 15. The control strategy generator of claim 13 , wherein the one or more processors are further adapted to: predict, using a simulated or mathematical model of the matrix converter and a load of the matrix converter, an output current of the matrix converter associated with each switching state in the reduced set of switching states; and perform a mathematical transformation on the predicted output current associated