Methods and apparatus for a single inductor multiple output (SIMO) DC-DC converter circuit

What is claimed is: 1. An apparatus, comprising: a single-inductor multiple-output (SIMO) DC-DC converter circuit, the SIMO DC-DC converter circuit having a plurality of output nodes; and a panoptic dynamic voltage scaling (PDVS) circuit operatively coupled to the SIMO DC-DC converter circuit, the PDVS circuit having a plurality of operational blocks, each operational block from the plurality of operational blocks drawing power from one supply voltage rail from a plurality of supply voltage rails, each output node from the plurality of output nodes being uniquely associated with a supply voltage rail from the plurality of supply voltage rails. 2. The apparatus of claim 1 , wherein: the SIMO DC-DC converter circuit including a first comparator and a second comparator, the first comparator is configured to receive a first bias current and produce a control signal to select a first output node from the plurality of output nodes when the first output node experiences a first load, the second comparator is configured to receive a second bias current and produce a control signal to select the first output node from the plurality of output nodes when the first output node experiences a second load lower than the first load, the second bias current being less than the first bias current, a power consumption of the second comparator being less than a power consumption of the first comparator when the SIMO DC-DC converter circuit is operative, the efficiency of the SIMO DC-DC converter being higher when the second comparator produces the control signal to select the first output node than when the first comparator produces the control the signal to select the first output node, the second comparator configured to be placed in an off mode with a power consumption less than a power consumption during an operative mode, when the first comparator produces the control signal to select the first output node, the first comparator configured to be placed in an off mode with a power consumption less than a power consumption during an operative mode, when the second comparator produces the control signal to select the first output node. 3. The apparatus of claim 1 , wherein the SIMO DC-DC converter circuit and the PDVS circuit are included within an integrated circuit (IC), the SIMO DC-DC converter circuit configured to prioritize a single output node from the plurality of output nodes within a time period based on which operational blocks from the plurality of operational block of the PDVS circuit connect to which supply voltage rails from the plurality of supply voltage rails during the time period. 4. The apparatus of claim 1 , wherein: the SIMO DC-DC converter circuit including a first comparator and a second comparator, the first comparator is configured to receive a first bias current and produce a control signal for a first output node from the plurality of output nodes, the second comparator is configured to receive a second bias current and produce a control signal for a second output node from the plurality of output nodes, the second bias current being less than the first bias current, an output voltage for the second output node being less than an output voltage for the first output node, a power consumption of the second comparator being less than a power consumption of the first comparator when the SIMO DC-DC converter circuit is operative. 5. The apparatus of claim 1 , wherein: the SIMO DC-DC converter circuit including a plurality of comparators and a plurality of switches operatively coupled to the plurality of comparators, each comparator from the plurality of comparators being uniquely associated with a switch from the plurality of switches, each switch from the plurality of switches being associated with an output node from the plurality of output nodes, the plurality of comparators collectively configured to send a control signal to control each switch from the plurality of switches such that current is sent to each output node from the plurality of output nodes based on the control signals, each comparator from the plurality of comparators is uniquely associated with a bias current from a plurality of bias currents, at least one bias current from the plurality of bias currents differing from the remaining bias currents from the plurality of bias currents, the plurality of comparators and the plurality of switches collectively configured to regulate the voltages on each output node from the plurality of output nodes. 6. The apparatus of claim 1 , wherein: the SIMO DC-DC converter circuit including a plurality of comparators and a plurality of switches operatively coupled to the plurality of comparators, each comparator from the plurality of comparators is configured to receive a bias current from a plurality of bias currents and a feedback signal from the output node for that comparator, at least one bias current from the plurality of bias currents differing from the remaining bias currents from the plurality of bias currents, the plurality of comparators and the plurality of switches collectively configured to select an output node from the plurality of output nodes based on (1) a condition of each output node from the plurality of output nodes, and (2) a relative priority of each output node from the plurality of output nodes. 7. The apparatus of claim 1 , wherein: the SIMO DC-DC converter circuit including a plurality of comparators and a plurality of switches operatively coupled to the plurality of comparators, each comparator from the plurality of comparators being uniquely associated with a switch from the plurality of switches, each comparator from the plurality of comparators being associated with a lower hysteresis threshold from the plurality of lower hysteresis thresholds and an upper hysteresis threshold from a plurality of upper hysteresis thresholds, each comparator from the plurality of comparators configured to produce a pulse having a width based on the hysteresis thresholds such that the uniquely associated switch is controlled in response to that pulse. 8. The apparatus of claim 1 , wherein: the SIMO DC-DC converter circuit including a plurality of comparators and a plurality of switches operatively coupled to the plurality of comparators, the plurality of comparators configured to prioritize a single output node from the plurality of output nodes within a time period based on which operational blocks from the plurality of operational block of the PDVS circuit connect to which supply voltage rails from the plurality of supply voltage rails during the time period, the plurality of comparators and the plurality of switches collectively configured to limit a ripple of an output voltage within a predefined range of each output node from the plurality of output nodes, the ripple of the output voltage for the single output node being less than the ripple of the output voltage for each remaining output node. 9. An apparatus, comprising: a single-inductor multiple-output (SIMO) converter circuit having a plurality of output nodes, a plurality of comparators, and a plurality of switches operatively coupled to the plurality of comparators, the plurality of comparators and the plurality of switches collectively: (1) configured to limit a ripple of an output voltage for the plurality of output nodes within a predefined range; and (2) configured to define a hysteretic-based output to control a plurality of output nodes, each comparator from the plurality of comparators being uniquely associated with an output node from the plurality of output nodes, each output node from the plurality of output nodes being uniquely associated with a circuit block from a plurality of circuit blocks. 10. Th