Battery Charging System with a Regulation Loop

What is claimed is: 1 . A charging system for a battery of an electronic device, wherein the charging system comprises, an adapter configured to derive a transfer current at a transfer voltage from a power source; a battery charger configured to charge a battery of the electronic device with a battery current at a battery voltage using the transfer current at the transfer voltage; power transmission means configured to transmit the transfer current at the transfer voltage to the battery charger; and communication means configured to transmit feedback information which is indicative of the battery voltage and/or the battery current from the battery charger to the adapter; wherein the adapter is configured to set the transfer voltage and/or the transfer current in dependence of the feedback information. 2 . The charging system of claim 1 , wherein the adapter and the battery charger are implemented in separate physical units, notably within separate integrated circuits; and/or the battery charger is implemented as part of the electronic device. 3 . The charging system of claim 1 , wherein the adapter comprises a voltage regulator which is configured to regulate the transfer voltage in dependence of the feedback information, such that the battery voltage is derivable from the transfer voltage by the battery charger using voltage step-down conversion with a conversion ratio of n, with n being an integer equal to or greater than 1. 4 . The charging system of claim 1 , wherein the battery charger comprises a current regulator configured to regulate the battery current for charging the battery using the transfer current at the transfer voltage. 5 . The charging system of claim 4 , wherein the current regulator exhibits a regulator voltage drop; and the adapter is configured to set the transfer voltage also in dependence of the regulator voltage drop. 6 . The charging system of claim 4 , wherein the battery charger comprises a control unit configured to determine a target charging current; the current regulator is configured to derive the battery voltage in dependence of the target charging current. 7 . The charging system of claim 1 , wherein the battery charger comprises a power converter which is configured to perform a step-down conversion of the transfer voltage by a conversion ratio n, wherein n is an integer greater than or equal to 1; and the adapter is configured to set the transfer voltage also in dependence of the conversion ratio n. 8 . The charging system of claim 7 , wherein the power converter comprises a capacitive power converter. 9 . The charging system of claim 7 , wherein the power converter exhibits a converter voltage drop; and the adapter is configured to set the transfer voltage also in dependence of the converter voltage drop. 10 . The charging system of claim 1 , wherein the power transmission means comprise a charging cable, notably a USB charging cable; and/or a wireless power transmission unit configured to generate an electromagnetic charging field using the transfer current at the transfer voltage; and a wireless power reception unit configured to derive power at the transfer voltage from the electromagnetic charging field. 11 . The charging system of claim 1 , wherein the battery charger comprises a transmission communication module configured to transmit the feedback information over a communication channel; and the adapter comprises a receiver communication module configured to receive the feedback information via the communication channel. 12 . The charging system of claim 11 , wherein the communication channel comprises an electrical wire of a charging cable which is used for conducting the transfer current at the transfer voltage from the adapter to the battery charger and/or a radio frequency link, such as a Bluetooth link, a WLAN link, a UMTS link and/or an LTE link. 13 . The charging system of claim 1 , wherein the adapter comprises a current regulator which is configured to regulate the transfer current in dependence of the feedback information, such that the battery voltage is derivable from the transfer voltage by the battery charger using voltage step-down conversion with a conversion ratio of n, with n being an integer equal to or greater than 1. 14 . The charging system of claim 1 , wherein the adapter may be configured to regulate the transfer voltage such that the transfer current does not exceed a pre-determined maximum transfer current; or regulate the transfer current such that the transfer voltage does not exceed a pre-determined maximum transfer voltage. 15 . An adapter for charging system for charging a battery of an electronic device, wherein the adapter comprises, a receiver communication module configured to receive feedback information which is indicative of a battery voltage and/or battery current to be used for charging the battery; a voltage regulator configured to derive a transfer current at a transfer voltage from a power source, in dependence of the feedback information; and a power transmission interface for providing the transfer current at the transfer voltage over power transmission means to a battery charger for charging the battery. 16 . An battery charger for charging a battery of an electronic device, wherein the battery charger comprises, a power reception interface for receiving a transfer current at a transfer voltage over power transmission means; a current regulator configured to regulate a battery current for charging the battery using the transfer current at the transfer voltage, wherein the battery current is to be provided at a battery voltage; and a transmission communication module configured to transmit feedback information indicative of the battery voltage and/or the battery current over a communication channel. 17 . A method for charging a battery of an electronic device using an adapter and a battery charger, wherein the adapter and the battery charger are separate from one another; the method comprising, deriving a transfer current at a transfer voltage from a power source using the adapter; transmitting the transfer current at the transfer voltage from the adapter to the battery charger; charging the battery of the electronic device with a battery current at a battery voltage, wherein the battery current is derived from the transfer current at the transfer voltage using the battery charger; and transmitting feedback information which is indicative of the battery voltage from the battery charger to the adapter ; wherein the transfer voltage and/or transfer current is set by the adapter in dependence of the feedback information. 18 . The method of claim 17 , wherein the adapter and the battery charger are implemented in separate physical units, notably within separate integrated circuits; and/or the battery charger is implemented as part of the electronic device. 19 . The method of claim 17 , wherein the adapter comprises a voltage regulator to regulate the transfer voltage in dependence of the feedback information, such that the battery voltage is derivable from the transfer voltage by the battery charger using voltage step-down conversion with a conversion ratio of n, with n being an integer equal to or greater than 1. 20 . The method of claim 17 , wherein the battery charger comprises a current regulator to regulate the battery current for charging the battery using the transfer current at the transfer voltage. 21 . The m