Adaptive modulation scheme of MOSFET driver key parameters for improved voltage regulator efficiency and system reliability

What is claimed is: 1. A voltage regulator, comprising: a power stage including: a high side switch including a high side gate; a peak voltage detection circuit coupled to the high side switch to provide a voltage stress level based on a high side output voltage of the high side switch; a high side driver strength modulator circuit coupled to the peak voltage detection circuit configured to: determine a high side driver strength level for a set of high side gate drivers based on a load current level of the power stage and the voltage stress level; connect a subset of the set of high side gate drivers to the high side gate based on the high side driver strength level; and disconnect a remaining subset of the set of high side gate drivers from the high side gate; and a dead-time management circuit configured to: adjust a programmable portion of a dead-time duration for the set of high side gate drivers and a set of low side gate drivers, the dead-time duration including the programmable portion of the dead-time duration and a dynamic portion of the dead-time duration proportional to a change in temperature of the power stage when the power stage is in an operating temperature region, wherein the programmable portion of the dead-time duration is adjusted to a low temperature duration value when the dead-time management circuit determines that a current temperature of the power stage is less than or equal to a low temperature region threshold, and wherein the programmable portion of the dead-time duration is adjusted to a high temperature duration value when the dead-time management circuit determines that the current temperature of the power stage is greater than or equal to a high temperature region threshold. 2. The voltage regulator of claim 1 , wherein higher positive load current levels correlate to higher driver voltage levels and lower positive load current levels correlate to lower driver voltage levels, and wherein higher magnitude negative load current levels correlate to higher driver voltage levels and lower magnitude negative load current levels correlate to lower driver voltage values. 3. The voltage regulator of claim 1 , the power stage further comprising: a low side switch including a low side gate; and a low side driver strength modulator circuit coupled to the peak voltage detection circuit configured to: determine a low side driver strength level for the set of low side gate drivers based on the load current level of the power stage and the voltage stress level; connect a subset of the set of low side gate drivers to the low side gate based on the low side driver strength level; and disconnect a remaining subset of the set of low side gate drivers from the low side gate. 4. The voltage regulator of claim 3 , wherein each of the high side switch and the low side switch is a metal-oxide-semiconductor-field-effect-transistors (MOSFETs). 5. The voltage regulator of claim 3 , further comprising: a driver strength modulator circuit including: a source impedance modulator circuit; a set of high side driver switches, each coupled between a corresponding high side gate driver of the set of high side gate drivers and the high side gate, wherein the connection of the subset of the set of high side gate drivers to the high side gate further comprises: the source impedance modulator circuit configured to close a subset of the set of high side driver switches to connect the subset of the set of high side gate drivers to the high side gate; a sink impedance modulator circuit; and a set of low side driver switches, each coupled between a corresponding low side gate driver of the set of low side gate drivers and the low side gate, wherein the connection of the subset of the set of low side gate drivers to the low side gate further comprises: the sink impedance modulator circuit configured to close a subset of the set of low side driver switches to connect the subset of the set of low side gate drivers to the low side gate. 6. The voltage regulator of claim 5 , further comprising: a driver voltage optimizer circuit configured to adjust a driver voltage level for the set of high side gate drivers and the set of low side gate drivers. 7. The voltage regulator of claim 6 , wherein the driver voltage optimizer circuit to adjust the driver voltage level is further configured to: reduce the driver voltage level when the driver voltage optimizer circuit determines that the load current level is less than or equal to a light load current threshold level; and increase the driver voltage level when the driver voltage optimizer circuit determines that the load current level is greater than a heavy load condition threshold level. 8. A method comprising: providing, by a peak voltage detection circuit of a power stage of a voltage regulator, a voltage stress level based on a high side output voltage of a high side switch of the power stage; determining, by a high side driver strength modulator circuit of the power stage, a high side driver strength level for a set of high side gate drivers of the power stage based on a load current level of the power stage and the voltage stress level; connecting a subset of the set of high side gate drivers to a high side gate of the high side switch based on the high side driver strength level; disconnecting a remaining subset of the set of high side gate drivers from the high side gate; and adjusting, by a dead-time management circuit, a programmable portion of a dead-time duration for the set of high side gate drivers and a set of low side gate drivers, wherein the dead-time duration includes the programmable portion of the dead-time duration and a dynamic portion of the dead-time duration proportional to a change in temperature of the power stage when the power stage is in an operating temperature region, and wherein adjusting the programmable portion of the dead-time duration for the set of high side gate drivers and the set of low side gate drivers comprises: determining when a current temperature of the power stage is less than or equal to a low temperature region threshold; in response to determining that the current temperature is less than or equal to the low temperature region threshold, adjusting the programmable portion of the dead-time duration for the set of high side gate drivers and the set of low side gate drivers to a low temperature duration value; determining when the current temperature of the power stage is greater than or equal to a high temperature region threshold; and in response to determining that the current temperature is greater than or equal to the high temperature region threshold, adjusting the programmable portion of the dead-time duration for the set of high side gate drivers and the set of low side gate drivers to a high temperature duration value. 9. The method of claim 8 , wherein higher positive load current levels correlate to higher driver voltage levels and lower positive load current levels correlate to lower driver voltage levels, and wherein higher magnitude negative load current levels correlate to higher driver voltage levels and lower magnitude negative load current levels correlate to lower driver voltage values. 10. The method of claim 8 , further comprising: determining, by a low side driver strength modulator circuit of the power stage, a low side driver strength level for the set of low side gate drivers of the power stage based on the load current level of the power stage and the voltage stress level; connecting a subset of the set of low side gate drivers to a low side gate of a low side switch based on the low side driver strength level; and disconnecting a remaining subset of the set