Systems and methods of increasing power converter efficiency

What is claimed is: 1. A power conversion unit comprising: a boost circuit comprising: an input configured to receive a direct current (DC) input voltage from a power supply, the DC input voltage ranging from a minimum input voltage value to a maximum input voltage value; boost circuitry coupled to the input and configured to boost the DC input voltage to a predefined nominal voltage value when the DC input voltage has a value between the minimum input voltage value and the predefined nominal voltage value, the predefined nominal voltage value being between the minimum and maximum input voltage values; and a bypass switch coupled in parallel to said boost circuitry, the bypass switch configured to bypass the boost circuitry based on the DC input voltage, wherein the bypass switch is closed such that the boost circuit outputs a maintained DC voltage when the DC input voltage has a value that is greater than or equal to the predefined nominal voltage value and less than the maximum input voltage value, the maintained DC voltage being equal to the DC input voltage; and a DC-DC converter coupled to and configured to receive an output of said boost circuit that is greater than or equal to the predefined nominal voltage value regardless of the DC input voltage value between the minimum and maximum input voltage values, the DC-DC converter configured to convert the one of the boosted DC voltage and the maintained DC voltage to a DC output voltage, wherein the DC-DC converter operates at substantially 100% duty cycle and at its highest efficiency at or above the predefined nominal voltage value. 2. The power conversion unit of claim 1 , wherein said boost circuit comprises: a boost circuit input configured to be coupled to the power supply; and a boost circuit output coupled to a DC link. 3. The power conversion unit of claim 2 , further comprising: a boost inductor series-coupled to a boost diode between said boost circuit input and said boost circuit output; and a boost MOSFET coupled at a first end to a common node defined between said boost inductor and said boost diode, and at a second end to earth ground. 4. The power conversion unit of claim 3 , further comprising: a bypass diode having a first end coupled to said boost circuit input and a second end coupled to said boost circuit output, said bypass diode configured to provide the DC input voltage directly to said DC-DC converter when said boost circuit maintains the DC input voltage; and wherein the bypass switch is a bypass MOSFET parallel-coupled to said bypass diode, said bypass MOSFET configured to increase efficiency of said power conversion unit. 5. The power conversion unit of claim 4 , wherein said boost circuit further comprises a synchronous MOSFET parallel-coupled to said boost diode, said synchronous MOSFET configured to increase efficiency of said power conversion unit. 6. The power conversion unit of claim 3 , wherein said boost circuit further comprises: a bypass diode having a first end coupled to said boost circuit input and a second end coupled to said boost circuit output, said bypass diode configured to protect said boost circuit from surge current when said boost circuit maintains the DC input voltage; and wherein the bypass switch is a synchronous MOSFET parallel-coupled to said boost diode, said synchronous MOSFET configured to increase efficiency of said power conversion unit. 7. The power conversion unit of claim 1 , wherein said boost circuit is further configured to boost the DC input voltage to up to two volts higher than the DC input voltage when the DC input voltage has a value that is greater than or equal to the predefined nominal voltage value and less than the maximum input voltage value. 8. The power conversion unit of claim 1 , wherein said DC-DC converter operates at a 100% duty cycle. 9. A method of improving efficiency in a power conversion unit, said method comprising: receiving, by a boost circuit, a direct current (DC) input voltage from a power supply, the DC input voltage ranging from a minimum input voltage value to a maximum input voltage value; boosting, using boost circuitry of the boost circuit, the DC input voltage to a predefined nominal voltage value when the DC input voltage has a value between the minimum input voltage value and the predefined nominal voltage value, the predefined nominal voltage value being between the minimum and maximum input voltage values; closing, by the boost circuit, a bypass switch to bypass the boost circuitry based on the DC input voltage, wherein the bypass switch is closed such that the boost circuit outputs a maintained DC voltage when the DC input voltage has a value that is greater than or equal to the predefined nominal voltage value and less than the maximum input voltage value, the maintained DC voltage being equal to the DC input voltage; receiving, by a DC-DC converter coupled to the boost circuit, an output of the boost circuit that is greater than or equal to the predefined nominal voltage value regardless of the DC input voltage value between the minimum and maximum input voltage values, wherein the DC-DC converter operates at substantially 100% duty cycle and at its highest efficiency at or above the predefined nominal voltage value; and converting, by the DC-DC converter, the one of the boosted DC voltage and the maintained DC voltage to a DC output voltage. 10. The method of claim 9 , further comprising providing, by a bypass diode having a first end coupled to a boost circuit input and a second end coupled to a boost circuit output, the DC input voltage directly to the DC-DC converter when the boost circuit is maintaining the DC input voltage. 11. The method of claim 10 , further comprising increasing efficiency of the power conversion unit using a bypass MOSFET parallel-coupled to the bypass diode. 12. The method of claim 11 , further comprising increasing efficiency of the power conversion unit using a synchronous MOSFET parallel-coupled to a boost diode of the power conversion unit. 13. The method of claim 9 , further comprising protecting the boost circuit from surge current when the boost circuit is maintaining the DC input voltage using a bypass diode having a first end coupled to a boost circuit input and a second end coupled to a boost circuit output. 14. The method of claim 9 , further comprising boosting the DC input voltage to up to two volts higher than the DC input voltage when the received DC input voltage has a value that is greater than or equal to the predefined nominal voltage value and less than the maximum input voltage value. 15. The method of claim 9 , further comprising operating the DC-DC converter at a 100% duty cycle. 16. A boost circuit comprising: an input configured to receive a direct current (DC) input voltage from a power supply, the DC input voltage ranging from a minimum input voltage value to a maximum input voltage value; boost circuitry coupled to the input and configured to boost the DC input voltage to a predefined nominal voltage value when the DC input voltage has a value between the minimum input voltage value and the predefined nominal voltage value, the predefined nominal voltage value being between the minimum and maximum input voltage values, wherein the boosted DC input voltage operates a DC-DC converter coupled to an output of said boost circuitry at substantially 100% duty cycle; and a bypass switch coupled in parallel to said boost circuitry, the bypass switch configured to bypass the boost circuitry based on the DC input voltage, wherein the bypass switch is closed such that the boos