Alpha–beta transformation

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In electrical engineering, the alpha-beta () transformation (also known as the Clarke transformation) is a mathematical transformation employed to simplify the analysis of three-phase circuits. Conceptually it is similar to the dq0 transformation. One very useful application of the transformation is the generation of the reference signal used for space vector modulation control of three-phase inverters.

Definition[edit]

The transform applied to three-phase currents, as used by Edith Clarke, is[1]

where is a generic three-phase current sequence and is the corresponding current sequence given by the transformation . The inverse transform is:

The above Clarke's transformation preserves the amplitude of the electrical variables which it is applied to. Indeed, consider a three-phase symmetric, direct, current sequence

where is the RMS of , , and is the generic time-varying angle that can also be set to without loss of generality. Then, by applying to the current sequence, it results

where the last equation holds since we have considered balanced currents. As it is shown in the above, the amplitudes of the currents in the reference frame are the same of that in the natural reference frame.

Power invariant transformation[edit]

The active and reactive powers computed in the Clark's domain with the transformation shown above are not the same of those computed in the standard reference frame. This happens because is not unitary. In order to preserve the active and reactive powers one has, instead, to consider

which is a unitary matrix and the inverse coincides with its transpose.[2] In this case the amplitudes of the transformed currents are not the same of those in the standard reference frame, that is

Finally, the inverse transformation in this case is

Simplified transformation[edit]

Since in a balanced system and thus one can also consider the simplified transform[3]

which is simply the original Clarke's transformation with the 3rd equation thrown away, and

Geometric Interpretation[edit]

The transformation can be thought of as the projection of the three phase quantities (voltages or currents) onto two stationary axes, the alpha axis and the beta axis.

Shown above is the transform as applied to three symmetrical currents flowing through three windings separated by 120 physical degrees. The three phase currents lag their corresponding phase voltages by . The - axis is shown with the axis aligned with phase 'A'. The current vector rotates with angular velocity . There is no component since the currents are balanced.

transform[edit]

The transform is conceptually similar to the transform. Whereas the transform is the projection of the phase quantities onto a rotating two-axis reference frame, the transform can be thought of as the projection of the phase quantities onto a stationary two-axis reference frame.

See also[edit]

References[edit]

  1. ^ W. C. Duesterhoeft; Max W. Schulz; Edith Clarke (July 1951). "Determination of Instantaneous Currents and Voltages by Means of Alpha, Beta, and Zero Components". Transactions of the American Institute of Electrical Engineers. 70 (2): 1248–1255. ISSN 0096-3860. doi:10.1109/T-AIEE.1951.5060554. 
  2. ^ S. CHATTOPADHYAY; M. MITRA; S. SENGUPTA (2008). "Area Based Approach for Three Phase Power Quality Assessment in Clarke Plane" (PDF). Journal of Electrical Systems. 04 (01): 62. Retrieved 2012-04-26. 
  3. ^ F. Tahri, A.Tahri, Eid A. AlRadadi and A. Draou Senior, "Analysis and Control of Advanced Static VAR compensator Based on the Theory of the Instantaneous Reactive Power," presented at ACEMP, Bodrum, Turkey, 2007.