Filter circuit

The invention claimed is: 1. A filter circuit comprising: a first input terminal; a reference terminal, wherein the filter circuit is configured to receive an input voltage waveform across the first input terminal and the reference terminal; a current regulation device; and a current sensing element, wherein: the current regulation device comprises a conduction channel and a control terminal, wherein the current regulation device is configured to regulate current flow through the conduction channel in accordance with a regulation-control-signal received at the current regulation device control terminal; and the current sensing element and the conduction channel of the current regulation device, are connected in series with each other between the first input terminal and the reference terminal; the filter circuit further comprising: a first feedback circuit configured to: receive a sensed-voltage-level-signal representative of a sensed voltage across the current sensing element; receive a voltage-set-point-signal; and set the regulation-control-signal such that the sensed-voltage-level-signal tends towards the voltage-set-point-signal; and a second feedback circuit configured to: receive a predetermined-threshold-signal; receive a regulation-control-voltage-signal, representative of a voltage level of the regulation-control-signal; and adjust the voltage-set-point-signal in accordance with a comparison between the regulation-control-voltage-signal and the predetermined-threshold-signal. 2. The filter circuit of claim 1 , wherein the second feedback circuit is configured to reduce the voltage-set-point-signal if the regulation-control-voltage-signal exceeds the predetermined-threshold-signal, and otherwise increase the voltage-set-point-signal. 3. The filter circuit of claim 1 , wherein the first feedback circuit is configured to regulate the regulation-control-signal at a first-regulation-bandwidth that is greater than that of a ripple component of the input voltage waveform. 4. The filter circuit of claim 3 , wherein the first-regulation-bandwidth is at least 5, 10, 100, 1,000 or 10,000 times greater than that of the ripple component of the input voltage waveform. 5. The filter circuit of claim 3 , wherein the frequency of the ripple component of the input voltage waveform is 100 Hz or 120 Hz. 6. The filter circuit of claim 1 , wherein the second feedback circuit is configured to reduce the voltage-set-point-signal if the regulation-control-voltage-signal exceeds the predetermined-threshold-signal, at a second-regulation-bandwidth that is less than that of a ripple component of the input voltage waveform. 7. The filter circuit of claim 6 , wherein the second-regulation-bandwidth is at least 10, 50, 100 or 200 times less than that of the ripple component of the input voltage waveform. 8. The filter circuit of claim 1 , wherein the first feedback circuit comprises: an error-amplifier comprising an error-amplifier-first-input-terminal, an error-amplifier-second-input-terminal and an error-amplifier-output-terminal, wherein: the error-amplifier-first-input-terminal is connected to the conduction channel of the current regulation device or the current sensing element in order to receive the sensed-voltage-level-signal ; the error-amplifier-second-input-terminal is connected to the second feedback circuit in order to receive the voltage-set-point-signal; and the error-amplifier-output-terminal is connected to the control terminal of the current regulation device. 9. The filter circuit of claim 8 , wherein the second feedback circuit comprises: a threshold-voltage-source configured to provide a signal that corresponds to the predetermin-threshold-signal, a set-point-discharge circuit connected to the error-amplifier-second-input-terminal, wherein the set-point-discharge circuit is configured to reduce the voltage-set-point signal if the regulation-control-voltage-signal exceeds the predetermined-threshold-signal, and a set-point-charge circuit connected to the error-amplifier-second-input-terminal, wherein the set-point-charge circuit is configured to increase the voltage-set-point signal if the regulation-control-voltage-signal does not exceed the predetermined-threshold-signal. 10. The filter circuit of claim 9 , wherein the discharge circuit comprises: an operational amplifier comprising an op-amp-first-input-terminal, an op-amp-second-input-terminal, and an op-amp-output-terminal, wherein: the op-amp-first-input-terminal is connected to the control terminal of the current-regulation-transistor in order to receive the regulation-control-voltage-signal, the op-amp-second-input-terminal is connected to the threshold-voltage-source, and the op-amp-output-terminal is connected directly or indirectly to the error-amplifier-second-input-terminal such that a signal at the op-amp-output-terminal can reduce the voltage-set-point-signal provided to the error-amplifier-second-input-terminal. 11. The filter circuit of claim 9 , wherein the threshold-voltage-source is configured to provide a voltage signal at a level that is below the maximum voltage that is available to drive the control terminal of the current regulation device. 12. The filter circuit of claim 9 , wherein the second feedback circuit also comprises a resistive divider, which includes a first-resistive-divider-resistor and a second-resistive-divider-resistor, wherein: the resistive divider is connected between the control terminal of the current regulation device and the reference terminal, and the node between the first-resistive-divider-resistor and the second-resistive-divider-resistor is connected to the op-amp-first-input-terminal. 13. A power converter circuit comprising: the filter circuit of any preceding claim; an LED load; and a PFC circuit; wherein a terminal of the LED load is connected to either the first input terminal or the reference terminal of the filter circuit, and wherein the LED load and the filter circuit are together connected in series across an output of the PFC circuit. 14. The power converter circuit of claim 13 , further comprising an output capacitor connected across the output of the PFC circuit. 15. An integrated circuit comprising the filter circuit of claim 1 . 16. A filter circuit comprising: a first input terminal; a reference terminal, wherein the filter circuit is configured to receive an input voltage waveform across the first input terminal and the reference terminal; a current regulation device; and a current sensing element, wherein: the current regulation device comprises a conduction channel and a control terminal, wherein the current regulation device is configured to regulate current flow through the conduction channel in accordance with a regulation-control-signal received at the current regulation device control terminal; and the current sensing element and the conduction channel of the current regulation device, are connected in series with each other between the first input terminal and the reference terminal; the filter circuit further comprising: a first feedback circuit configured to: receive a sensed-voltage-level-signal representative of a sensed voltage across the current sensing element; receive a voltage-set-point-signal; and set the regulation-control-signal such that the sensed-voltage-level-signal tends towards the voltage-set-point-signal; and a second feedback circuit configured to: receive a predetermined-threshold-signal; receive a regulation-control-voltage-signal, representative of a voltage level of the re