Variable optical attenuator

What is claimed is: 1. A variable optical attenuator comprising: a polarization beam splitter that splits a beam incoming from the front along one light path into a first linearly-polarized beam and a second linearly-polarized beam, with polarization planes thereof perpendicular to each other as well as outputting the first linearly-polarized beam and the second linearly-polarized beam individually along two parallel light paths going to the back; a variable Faraday rotator that is configured to include a Faraday element composed of magneto-optical materials and a magnetism applying means of variably controlling the direction and the magnitude of a magnetic field to be applied to the Faraday element and rotates each of the polarization planes of the first linearly-polarized beam and the second linearly-polarized beam individually incoming from the polarization beam splitter along the two parallel light paths by controlling the magnetic field to be applied to the Faraday element by the magnetism applying means, outputting them as a third linearly-polarized beam and a fourth linearly-polarized beam, respectively, further to the back; a first analyzer that is configured to have an optical axis of the same direction as that of the polarization plane of the first linearly-polarized beam and modulates the third linearly-polarized beam incoming from the variable Faraday rotator to a component in the direction of the polarization plane of the first linearly-polarized beam for outputting it as a fifth linearly-polarized beam; and a second analyzer that is configured to have the optical axis of the same direction as that of the polarization plane of the second linearly-polarized beam and modulates the fourth linearly-polarized beam incoming from the variable Faraday rotator to the component in the direction of the polarization plane of the second linearly-polarized beam for outputting it as a sixth linearly-polarized beam, the fifth linearly-polarized beam propagating in a first light path and being input to a first 90° optical hybrid without additional splitting before arriving at the first 90° optical hybrid, the first 90° optical hybrid being arranged at a subsequent stage of the variable optical attenuator, the sixth linearly-polarized beam propagating in a second light path and being input to a second 90° optical hybrid without additional splitting before arriving at the second 90° optical hybrid, the second 90° optical hybrid being arranged at a subsequent stage of the variable optical attenuator. 2. The variable optical attenuator of claim 1 , further comprising: a network tap that is disposed in the one light path anterior to the polarization beam splitter and outputs a part of the beam incoming from the front toward the polarization beam splitter along the one light path as well as causing the other part thereof to diverge as a diverging beam to output an electric signal corresponding to the received beam intensity of the diverging beam. 3. The variable optical attenuator of claim 1 , wherein the polarization beam splitter is a double refraction element that splits a beam incoming from the front into the ordinary light as the first linearly-polarized beam and the extraordinary light as the second linearly-polarized beam, and wherein the variable optical attenuator further comprises: a phase-compensating plate arranged posterior to the first analyzer and the second analyzer to compensate for a phase difference between the ordinary light and the extraordinary light. 4. The variable optical attenuator of claim 1 , wherein the magnetism applying means is composed of an electromagnet to apply a variable magnetic field in the anteroposterior direction, and a permanent magnet to apply saturated magnetism in the direction perpendicular to the light path, to the Faraday element. 5. The variable optical attenuator of claim 1 , wherein the magnetism applying means is composed of an electromagnet to apply a variable magnetic field in the direction perpendicular to the light path, and a permanent magnet to apply saturated magnetism in the anteroposterior direction, to the Faraday element, and wherein the electromagnet is so constructed that both ends of a C-shaped yoke will sandwich the Faraday element from the direction perpendicular to the light path and the permanent magnet is of a hollow-cylindrical shape and is arranged anterior or posterior to the Faraday element.