Charger antenna unit, charger device, and device to be charged

1 . A charger configured to charge a device to be wirelessly charged, the charger comprising: an antenna unit for charging a device to be inductively charged, the antenna unit including: an excitation coil made of an electrical conductor wound around a toroidal core to excite a magnetic field inside the toroidal core, the toroidal core having an air-gap between two end-faces of the toroidal core, wherein the two end-faces are facing each other, wherein the end-faces of the antenna unit are configured to be parallel to each other, and the winding density of the excitation coil along the toroidal length of the toroidal core is higher in the vicinity of the respective end-faces as compared to the remaining parts of the toroidal core, and a housing having an opening adapted to be aligned with the device to be inductively charged, such that a receiving antenna of the device to be inductively charged can at least partially be inserted into the air-gap of the toroidal core of the charger antenna unit, wherein a magnetic shield is provided in the housing at the toroidal core, wherein the magnetic shield is at least partly provided as a coating or plating on a carrier medium. 2 . The charger according to claim 1 , wherein the toroidal core of the antenna unit is composed of one or more core parts, adjoining each other. 3 . The charger according to claim 2 , wherein the one or more core parts are arranged with respect to each other, so that the air-gap can be adjusted in terms of its gap width. 4 . The charger according to claim 1 , wherein the carrier medium is made from a thermoplastic resin, such as ABS, such as ABS resin, such as PVC, or the like. 5 . The charger according to claim 1 , wherein the magnetic shield is made out of at least one material selected from copper, copper-alloy, aluminum, or a material having high electrical conductivity allowing the occurrence of eddy currents in the material, or the magnetic shielding is made out of at least one material selected from mu-metal, permalloy, supermalloy, soft ferromagnetic alloy, or a material having a high magnetic permeability and low magnetic coercitivity. 6 . The charger according to claim 5 , wherein the magnetic shielding is composed of a first magnetic shielding part and a second magnetic shielding part, and the first magnetic shielding part and the second magnetic shielding part are separated from each other by slits having a toroidal shape in a plane parallel to the plane of the toroidal core of the charger antenna unit. 7 . The charger according to claim 6 , wherein the first magnetic shielding part and the second magnetic shielding part are galvanically connected. 8 . The charger according to claim 1 , further comprising: detector, configured to detect the presence and/or absence of the device to be inductively charged, receiver, configured to receive information relating to a charge state of a rechargeable battery of the device to be inductively charged, driver, configured to supply power to the charger antenna unit of the charger unit, controller, configured to control the driver in response to received information received by the receiver, wherein the controller is configured to control the driver to supply power to the charger antenna unit only in case the detector has detected the presence of the device to be inductively charged. 9 . The charger according to claim 8 , further comprising: transmitter, configured to transmit information to the device to be inductively charged, and wherein the receiver is configured to receive information from the device to be inductively charged. 10 . The charger according to claim 9 , wherein the transmitter and the receiver are configured to transmit and to receive information using the charger antenna unit. 11 . A charger configured with an opening to receive a device to be wirelessly charged, the charger comprising: an excitation coil made of an electrical conductor wound around a toroidal core to excite a magnetic field inside the toroidal core, the toroidal core having an air-gap between two end-faces of the toroidal core, wherein the air-gap is shaped to receive the device to be wirelessly charged including a receiving antenna, and wherein a magnetic shield is provided in the housing at the toroidal core, wherein the magnetic shield is at provided as an encapsulating unit configured to encapsulate the toroidal core, wherein a slit is formed in the encapsulating unit. 12 . The charger according to claim 11 , wherein winding density of the excitation coil along the toroidal length of the toroidal core is higher in a section at the respective end-faces as compared to the remaining parts of the toroidal core. 13 . A system comprising a charger according to claim 1 , and a device to be inductively charged, wherein the device to be inductively charged comprises: a rechargeable battery for storing power used to operate the device to be inductively charged, charge state detector to detect the charge state of the rechargeable battery, a receiving antenna, configured to receive electromagnetic energy from a charger device for charging the rechargeable battery, receiver, configured to receive information from a charger device, a transmitter configured to transmit information to the charger device, and a controller configured to control the transmitter to transmit the charge state detected by the rechargeable battery charge state detector to the charger device. 14 . The system according to claim 13 , herein the device to be inductively charged further comprises: a shielding unit, configured to magnetically shield the rechargeable battery from external electromagnetic fields from the charger during the charging process. 15 . The system according to claim 14 , wherein the shielding unit in the device to be inductively charged is provided directly on the rechargeable battery. 16 . The system according to claim 13 , wherein the device to be inductively charged further comprises a coil for high-frequency communication, wherein the coil is used as the receiving antenna of the device to be inductively charged.