Electric linear motion actuator

What is claimed is: 1. An electric linear motion actuator comprising: an electric motor; a linear motion mechanism having a rotation input-output shaft and being configured to convert rotary motion of the electric motor to linear motion of a linear motion part by use of the rotation input-output shaft; and a main housing holding the linear motion mechanism, wherein the electric motor is provided with a stator and a rotor, wherein the stator and the rotor are arranged such that directions of magnetic poles that generate interlinkage flux contributing to a motor torque are parallel with a rotation axis of the electric motor, the stator is arranged so as to be coupled with an axial end surface of the main housing, the rotor is arranged so as to have a space, in an axial direction, from a torque generating surface of the stator, and the rotor is fixed to the rotation input-output shaft of the linear motion mechanism, a first positioning structure, configured to coaxially couple the stator and the axial end surface of the main housing, provided so as to extend across the stator and the main housing, and the first positioning structure is implemented by fitting between an inner circumferential surface of one of a first housing of the stator and the main housing and an outer circumferential surface of the other of the first housing of the stator and the main housing. 2. The electric linear motion actuator as claimed in claim 1 , wherein the rotor is a magnetic field mechanism having a torque generating surface on each of both surfaces, opposite in the axial direction, of the rotor, the stator is provided with first and second excitation mechanisms respectively arranged on both surfaces, in the axial direction, of the magnetic field mechanism, the first positioning structure is configured to coaxially couple the first excitation mechanism and the axial end surface of the main housing, and is provided so as to extend across the first excitation mechanism and the main housing, the rotor is fixed, to the rotation input-output shaft, at an axial position corresponding to a portion between the first excitation mechanism and the second excitation mechanism, a second positioning structure configured to coaxially couple the first and second excitation mechanisms is provided so as to extend across the first and second excitation mechanisms, and the second positioning structure is implemented b fitting between an inner circumferential surface of one of the first housing of the first excitation mechanism and a second housing of the second excitation mechanism and an outer circumferential surface of the other of the first housing of the first excitation mechanism and the second housing of the second excitation mechanism. 3. The electric linear motion actuator as claimed in claim 1 , wherein the stator is a third excitation mechanism having the torque generating surface on each of both surfaces, opposite in the axial direction, of the stator, the rotor is provided with two magnetic field mechanisms that are respectively arranged on both surfaces, opposite in the axial direction, of the third excitation mechanism, and one magnetic field mechanism of the two magnetic field mechanisms is fixed, to the rotation input-output shaft, at an axial position corresponding to a portion between the axial end surface of the main housing and the torque generating surface of the third excitation mechanism facing the axial end surface. 4. The electric linear motion actuator as claimed in claim 3 , wherein a third positioning structure is implemented by fitting between an inner circumferential surface of one of a third housing of the third excitation mechanism and a motor cover and an outer circumferential surface of the other of the third housing of the third excitation mechanism and the motor cover. 5. An electric brake device comprising: the electric linear motion actuator as claimed in claim 1 ; a brake rotor; and a friction member configured to generate a braking force by coming into contact with the brake rotor. 6. The electric linear motion actuator as claimed in claim 2 , wherein the first and second excitation mechanisms are fastened to the main housing with common bolts, or the first excitation mechanism and the main housing are coupled with each other. 7. The electric linear motion actuator as claimed in claim 3 , wherein the third excitation mechanism and the main housing are coupled with each other.