Multiple output voltage conversion

The invention claimed is: 1. Voltage dividing circuitry for use in a voltage converter for converting at least one input Direct Current (DC) voltage to a plurality of output DC voltages, the voltage dividing circuitry comprising: a first voltage input port to receive an input DC voltage; an inductor comprising an input-side switch node and an output-side switch node, wherein the output-side switch node is connectable to one of a plurality of voltage output ports to supply a converted value of the input DC voltage as an output DC voltage; and a flying capacitor interface comprising a plurality of switching elements coupled in series with the first voltage input port, a first flying capacitor connected in parallel across a first number of switching elements of the plurality of switching elements, and a second flying capacitor connected in parallel across a second number of switching elements of the plurality of switching elements and across the first flying capacitor, wherein the second number of switching elements includes the first number of switching elements and is greater than the first number of switching elements, and the flying capacitor interface is to divide the input DC voltage to provide a predetermined fixed ratio of the input DC voltage at the input-side switch node of the inductor; and a second voltage input port coupled to the input-side switch node of the inductor by a switching element, wherein the second voltage input port is to receive a second input DC voltage, and the first voltage input port and the second voltage input port are connectable in parallel to the input-side switch node of the inductor. 2. Voltage dividing circuitry as claimed in claim 1 , wherein the voltage dividing circuitry is arranged to alternately connect the input-side switch node of the inductor to the predetermined fixed ratio of the input DC voltage during a first phase of a buck-boost operation and to ground during a second phase of the buck-boost operation. 3. Voltage dividing circuitry as claimed in claim 1 , wherein the voltage dividing circuitry comprises an inductor grounding switching element arranged to alternately connect the output-side switch node of the inductor to ground in a first phase of an operation and to one of the plurality of voltage output ports in a second phase of the operation, and the operation comprises a boost operation or a buck-boost operation. 4. Voltage dividing circuitry as claimed in claim 1 , wherein each of the first and second flying capacitors is to provide, upon charge or discharge of at least a subset of the first and second flying capacitors, the predetermined fixed ratio of the input DC voltage at the input-side switch node. 5. Voltage dividing circuitry as claimed in claim 1 , wherein the predetermined fixed ratio is a ratio of a number of the first number of switching elements to a total number of switching elements in the plurality of switching elements. 6. Voltage dividing circuitry as claimed in claim 1 , wherein: the voltage dividing circuitry is operable in a boost mode, a buck mode and a buck-boost mode; in a first phase of the boost mode, the input-side switch node is held at a voltage equal to the predetermined fixed ratio of the input DC voltage while the output-side switch node is grounded; in a second phase of the boost mode, the input-side switch node is held at the voltage equal to the predetermined fixed ratio of the input DC voltage while the output-side switch node is connected to one of the plurality of voltage output ports; in a first phase of the buck mode, the input-side switch node is connected to a non-zero voltage while the output-side switch node is connected to the one of the plurality of voltage output ports; in a second phase of the buck mode, the input-side switch node is grounded while the output-side switch node is connected to the one of the plurality of voltage output ports; in a first phase of the buck-boost mode, the input-side switch node is held at a voltage equal to the predetermined fixed ratio of the input DC voltage while the output-side switch node is grounded; and in a second phase of the buck-boost mode, the input-side switch node is grounded while the output-side switch node is connected to the one of the plurality of voltage output ports. 7. Voltage dividing circuitry as claimed in claim 1 , wherein in a buck-boost mode, a first phase of operation is an energy-storing phase of the inductor, and a second phase of operation is an energy-releasing phase of the inductor; in the energy-storing phase, the output-side switch node of the inductor is connected either to ground or to one of the plurality of voltage output ports corresponding to a higher voltage than a voltage at the input-side switch node; in the energy-releasing phase, the output-side switch node of the inductor is connected to one of the plurality of voltage output ports; and timings of transitions between the energy-storing phase and the energy releasing phase are controlled to provide at the output-side switch node, depending on the relative timings, either a step-up in voltage or a step-down in voltage relative to the predetermined fixed ratio of the input DC voltage at the input-side switch node. 8. Voltage dividing circuitry as claimed in claim 7 , wherein the relative timings of the transitions between the energy-storing phase and the energy-releasing phase are controlled to provide the step-up in voltage and the voltage dividing circuitry is arranged to connect the output-side voltage node to one of the plurality of voltage output ports corresponding to the higher voltage than the voltage at the input-side switch node in the first phase. 9. Voltage dividing circuitry as claimed in claim 7 , wherein the relative timings of the transitions between the energy-storing phase and the energy-releasing phase are controlled to provide the step-down in voltage and to connect the output-side voltage node to one of the plurality of voltage output ports corresponding to a lower voltage than the predetermined fixed ratio of the input DC voltage. 10. Voltage dividing circuitry as claimed in claim 1 , wherein the voltage dividing circuitry is responsive to control signals from a controller to transition between states of a sequence of different states to balance voltages on the first and second flying capacitors. 11. Voltage dividing circuitry as claimed in claim 10 , wherein the controller is to select a target state of the sequence of different states from a present state of the sequence of different states depending on a measurement of a voltage across each of the first and second flying capacitors in the present state and further depending on a measurement of the input DC voltage. 12. Voltage dividing circuitry as claimed in claim 11 , wherein the controller is to select the target state by determining if a voltage across each flying capacitor in the present state is high or low relative to a nominal voltage for the respective flying capacitor, the nominal voltage being a predetermined fraction of the determined input voltage. 13. Voltage dividing circuitry as claimed in claim 11 , wherein the controller is to control each transition between different states of the sequence of different states to ensure that no more than a predetermined number of switching elements change their respective switching state for any given state transition by switching to an intermediate state prior to the target state if the predetermined number of switch state changes would otherwise be violated. 14. Voltage dividing circuitry as claimed in claim 10 , wherein the states of the sequence of different states are selected s