Abstract: In a phased array antenna that has a configuration in which a plurality of antenna panels, in each of which a plurality of antenna elements are arrayed, are connected in the form of a plane and that radiates power transmission microwaves in the arrival direction of a pilot signal sent from an electric-power receiving facility (rectenna system), by controlling the phases of signals input to and output from the antenna elements. An arithmetic processing section, which is provided in each of the antenna panels, calculates the phase shifts of power transmission microwaves to be radiated from the antenna elements. Then, the phase information indicating the phase shifts calculated by the arithmetic processing section is sent to at least three adjacent antenna panels by a transmission and reception section provided in each of the antenna panels.

Abstract: A charging apparatus for an electric vehicle, the electric vehicle is parked on a power transmission unit provided on the ground, a power receiving unit provided on a lower surface of a vehicle body of the electric vehicle is aligned with the power transmission unit, and the power receiving unit receives electric power energy aerially fed from the power transmission unit to charge a battery mounted on the electric vehicle in a non-contact manner, and the charging apparatus includes a shielding unit for shielding an operation surface of the power receiving unit from outside without hindering power transmission and receiving action. A rolling screen is preferable as the shielding unit.

Abstract: A power receiving device includes: a plurality of antennas, a plurality of rectenna rectifying circuits each of which is provided to correspond to each of the antennas and each of which converts electromagnetic waves received by the corresponding antenna into DC power and outputs the DC power; a connection switching circuit which is provided between the plurality of rectenna rectifying circuits and a load and which performs switching between serial/parallel connection states of the output side of the plurality of rectenna rectifying circuits; a current sensor which measures current flowing through the load; and a control section which, on the basis of the current measured by the current sensor, selects a serial/parallel connection state of the rectenna rectifying circuits, the state enabling the RF-DC conversion efficiency to be maximized, and which controls the connection switching circuit so that the rectenna rectifying circuits is in the selected serial/parallel connection state.

Abstract: It is desired to provide a wireless power transmission system which it is possible to more surely prevent the leakage of a microwave. A wireless power transmission system includes: a power transmission antenna configured to output a microwave from an output plane; a power reception antenna arranged in a position opposing to said output plane of said power transmission antenna in power transmission and configured to receive the microwave outputted from said power transmission antenna by an input plane; and a shield section configured to electromagnetically shield a space between said power transmission antenna and said power reception antenna from an external space by a plurality of outer circumference coil springs provided in an area which surrounds said output plane of said power transmission antenna. The coil spring bends along a convex section compared with a wire member when there is the convex section in a hit part. Therefore, good electromagnetic wave shield efficiency is obtained.

Abstract: In a phased array antenna that has a configuration in which a plurality of antenna panels, in each of which a plurality of antenna elements are arrayed, are connected in the form of a plane and that radiates power transmission microwaves in the arrival direction of a pilot signal sent from an electric-power receiving facility (rectenna system), by controlling the phases of signals input to and output from the antenna elements. An arithmetic processing section, which is provided in each of the antenna panels, calculates the phase shifts of power transmission microwaves to be radiated from the antenna elements. Then, the phase information indicating the phase shifts calculated by the arithmetic processing section is sent to at least three adjacent antenna panels by a transmission and reception section provided in each of the antenna panels.

Abstract: A charging apparatus for an electric vehicle, the electric vehicle is parked on a power transmission unit provided on the ground, a power receiving unit provided on a lower surface of a vehicle body of the electric vehicle is aligned with the power transmission unit, and the power receiving unit receives electric power energy aerially fed from the power transmission unit to charge a battery mounted on the electric vehicle in a non-contact manner, and the charging apparatus includes a shielding unit for shielding an operation surface of the power receiving unit from outside without hindering power transmission and receiving action. A rolling screen is preferable as the shielding unit.

Abstract: The precision of phase correction is improved. Provided are a detection unit (40) that detects a phase of arrival of a pilot signal at each of antenna panel on the basis of the pilot signal and a reference signal commonly transmitted to each antenna panel; a position specifying unit (51) that specifies a position of each of the antenna panels relative to a reference panel defined as an antenna panel for reference among the plurality of the antenna panels, on the basis of the phase of arrival and an angle of arrival formed between the direction of arrival of the pilot signal and the antenna panel; and a phase-shift setting unit (52) that sets respective phase shifts for the signals radiated from individual antenna elements on the basis of information about the positions of the antenna panels specified by the position specifying unit (51).

Abstract: To improve RF-DC conversion efficiency even when input power is varied.

Abstract: It is desired to provide a wireless power transmission system which it is possible to more surely prevent the leakage of a microwave. A wireless power transmission system includes: a power transmission antenna configured to output a microwave from an output plane; a power reception antenna arranged in a position opposing to said output plane of said power transmission antenna in power transmission and configured to receive the microwave outputted from said power transmission antenna by an input plane; and a shield section configured to electromagnetically shield a space between said power transmission antenna and said power reception antenna from an external space by a plurality of outer circumference coil springs provided in an area which surrounds said output plane of said power transmission antenna. The coil spring bends along a convex section compared with a wire member when there is the convex section in a hit part. Therefore, good electromagnetic wave shield efficiency is obtained.