Multistage axial flow compressor

The invention claimed is: 1. A multi-stage axial compressor comprising: a flow path having a plurality of compressor stages each including a rotor and a stator downstream of the rotor with respect to a flow direction of the flow path, the flow path defined between annular inner and outer walls converging from an upstream inlet end to a downstream outlet end of the compressor, the inner and outer walls having a smaller radius at the outlet end than at the inlet end; wherein the inner wall is stepped from the inlet end to the outlet end to define a step portion for each of the stages, each step portion extending across at least a majority of an axial length of the stage, and the inner wall has a transition portion shaped as a smooth curve between adjacent step portions, each transition portion having a steeper axial slope than that of the adjacent step portions, each transition portion having a smaller radius at a downstream one of the adjacent step portions than at an upstream one of the adjacent step portions. 2. The multi-stage axial compressor as defined in claim 1 , wherein a reference line is defined for each stage extending from an intersection of a leading edge of a blade of the rotor with the inner wall to an intersection of a trailing edge of a vane of the stator with the inner wall, and each step portion forms an angle of from 1° to 5° with the reference line of the stage. 3. The multi-stage axial compressor as defined in claim 1 , wherein each step portion includes a point on the inner wall radially aligned with a maximum thickness of an airfoil portion of a blade of the rotor. 4. The multi-stage axial compressor as defined in claim 1 , wherein each step portion begins at or downstream of an intersection of a leading edge of a blade of the rotor with the inner wall. 5. The multi-stage axial compressor as defined in claim 1 , wherein each step portion ends from 0% to 20% of an axial chord length of a vane of the stator along the inner wall upstream of an intersection of a trailing edge of the vane with the inner wall. 6. The multi-stage axial compressor as defined in claim 1 , wherein each step portion has an upstream end radially outward of a downstream end of the step portion. 7. The multi-stage axial compressor as defined in claim 1 , wherein each step extends parallel to a central axis of the compressor. 8. The multi-stage axial compressor as defined in claim 7 , wherein the slope of each step portion is constant. 9. The multi-stage axial compressor as defined in claim 1 , wherein each step portion defines a step line along the inner wall, and each transition portion is defined as a smooth tangent blend between the step lines of the adjacent step portions. 10. A multi-stage axial compressor comprising: a flow path having a plurality of compressor stages each including a rotor and a stator downstream of the rotor with respect to a flow direction of the flow path, the flow path defined between annular inner and outer walls converging from an upstream inlet end to a downstream outlet end of the compressor, the inner and outer walls having a smaller radius at the outlet end than at the inlet end; wherein the inner wall is stepped from the inlet end to the outlet end to define a step portion for each of the stages, each step portion including a point on the inner wall radially aligned with a maximum thickness of an airfoil portion of a blade of the rotor of the stage and a point on the inner wall radially aligned with a maximum thickness of an airfoil portion of a vane of the stator of the stage, and the inner wall has a transition portion shaped as a smooth curve and connecting each adjacent ones of the step portions, each transition portion converging radially inwardly from an upstream one of the adjacent step portions to a downstream one of the adjacent step portions, each transition portion having a steeper slope than that of the adjacent step portions. 11. The multi-stage axial compressor as defined in claim 10 , wherein a reference line is defined for each stage extending from an intersection of a leading edge of a blade of the rotor with the inner wall to an intersection of a trailing edge of a vane of the stator with the inner wall, and each step portion forms an angle of from 1° to 5° with the reference line of the stage. 12. The multi-stage axial compressor as defined in claim 10 , wherein each step portion begins at or downstream of an intersection of a leading edge of a blade of the rotor with the inner wall. 13. The multi-stage axial compressor as defined in claim 10 , wherein each step portion ends from 0% to 20% of an axial chord length of a vane of the stator along the inner wall upstream of an intersection of a trailing edge of the vane with the inner wall. 14. The multi-stage axial compressor as defined in claim 10 , wherein each step portion has an upstream end radially outward of a downstream end of the step portion. 15. The multi-stage axial compressor as defined in claim 10 , wherein each step extends parallel to a central axis of the compressor. 16. The multi-stage axial compressor as defined in claim 10 , wherein the slope of each step portion is constant. 17. The multi-stage axial compressor as defined in claim 10 , wherein each step portion defines a step line along the inner wall, and each transition portion is defined as a smooth tangent blend between the step lines of the adjacent step portions. 18. A method of directing flow through an axial flow compressor having multiple stages, the method comprising: providing a plurality of successive compressor stages each including a stator and a rotor extending across a flow path, the stator located downstream of the rotor with respect to a direction of the flow; for each of the compressor stages, directing the flow along a radially inner wall defining the flow path through a portion of the flow path including at least a majority of an axial length of the stage in a first direction having a first slope with respect to an axial direction of the compressor; and between adjacent ones of the stages, directing the flow along the radially inner wall in a second direction angled toward a central axis of the compressor with a second slope greater than each first slope and defining a smooth curve. 19. The method as defined in claim 18 , wherein directing the flow in the first direction comprises accelerating the flow. 20. The method as defined in claim 18 , wherein directing the flow in the first direction and in the second direction comprises limiting flow separation with respect to the radially inner wall. 21. The method as defined in claim 18 , wherein directing the transition portion is aerodynamically configured to reduce an adverse static pressure gradient between the stages.