N+1 power supply system upgrade using dual output power supplies

What is claimed: 1. A system comprising: a power module comprising a plurality of power supplies that are connected, one or more power supplies, of the plurality of power supplies, being operable at a plurality of voltages; and a controller, coupled to the one or more power supplies, to: determine, while the system is operating at a first voltage and after one or more other power supplies are replaced with the one or more power supplies, that the plurality of power supplies are sufficient to run the system at a second voltage; and ramp up, based on determining that the plurality of power supplies are sufficient to run the system at the second voltage, an output voltage, associated with the plurality of power supplies, from the first voltage to the second voltage in a plurality of steps, the first voltage being greater than zero volts, each of the plurality of steps being less than one volt, and ramping up, based on determining that the plurality of power supplies are sufficient to run the system at the second voltage, the output voltage by a particular step, of the plurality of steps, being performed while a load is receiving power from the plurality of power supplies. 2. The system of claim 1 , where the load includes one or more line cards installed in a chassis frame or one or more fabric cards installed in the chassis frame. 3. The system of claim 2 , where the controller is installed on one of: a backplane of the chassis frame, a line card installed in the chassis frame, or a fabric card installed in the chassis frame. 4. The system of claim 1 , where the plurality of power supplies includes N+1 active power supplies, and an active power supply, of the N+1 active power supplies, is redundant. 5. The system of claim 1 , where a power supply, of the plurality of power supplies, includes: a direct current (DC) power stage to convert an input DC voltage into an output DC voltage; a resistive divider, coupled to the DC power stage, to control the output DC voltage, where the resistive divider includes a digital potentiometer; and a slave controller to: receive a command from the controller, the command specifying the output DC voltage; determine a setting of the digital potentiometer based on the received command; and set the digital potentiometer to the determined setting. 6. The system of claim 5 , where the power supply, of the plurality of power supplies, further comprises: an alternating current (AC) to DC converter coupled with the DC power stage to convert an input AC voltage into an output DC voltage; a pulse width modulator, coupled to the DC power stage, to control the output DC voltage of the DC power stage, the pulse width modulator to: receive an input from a sawtooth wave generator; receive an input from an error amplifier, the error amplifier taking as an input a combination of a signal taken from the resistive divider and a compensation circuit; and combine the inputs from the sawtooth wave generator and the error amplifier to generate a pulse signal, where a duty cycle of the pulse signal is proportional to an output voltage generated by the error amplifier. 7. The system of claim 1 , where the controller, when ramping up the output voltage from the first voltage to the second voltage, is further to: instruct the power module to ramp up the output voltage by a step voltage; wait, based on instructing the power module to ramp up the output voltage by the step voltage, for a particular length of time; determine, after the particular length of time, whether all of the plurality of power supplies are outputting a same voltage; determine, when the plurality of power supplies are outputting the same voltage, whether the second voltage has been reached; and instruct, when the second voltage has not been reached, the power module to ramp up the output voltage by another step voltage. 8. The system of claim 7 , where the controller is further to: identify, when all of the plurality of power supplies are not outputting the same voltage, a power supply, of the plurality of power supplies, associated with an output voltage that is less than an output voltage associated with another power supply of the plurality of power supplies; and ramp up the output voltage of the identified power supply to match an output voltage associated with at least one other power supply of the plurality of power supplies. 9. The system of claim 1 , where the controller is further to: poll, when the power module is outputting the second voltage, the plurality of power supplies at particular intervals to determine whether all of the plurality of power supplies are outputting a same voltage. 10. A method comprising: determining, by a device, that an output voltage, associated with a plurality of power supplies that are connected, is at a first voltage, one or more power supplies, of the plurality of power supplies, being operable at a plurality of voltages, and the plurality of power supplies being associated with a power module; determining, by the device, while a system is operating at the first voltage, and after one or more other power supplies are replaced with the one or more power supplies, that the plurality of power supplies are sufficient to run the system at a second voltage; and ramping up, by the device, based on determining that the output voltage is at the first voltage, and based on determining that the plurality of power supplies are sufficient to run the system at the second voltage, the output voltage to the second voltage in a plurality of steps, the first voltage being greater than zero volts, each of the plurality of steps being less than one volt, and ramping up, based on determining that the plurality of power supplies are sufficient to run the system at the second voltage, the output voltage by a particular step, of the plurality of steps, being performed while a load is receiving power from the plurality of power supplies. 11. The method of claim 10 , where the plurality of power supplies includes N+1 active power supplies, and an active power supply, of the N+1 active power supplies, is redundant. 12. The method of claim 10 , where, when ramping up the output voltage from the first voltage to the second voltage, the method includes: instructing the power module to ramp up the output voltage by a step voltage; waiting, based on instructing the power module to ramp up the output voltage by the step voltage, for a particular length of time; determining, after the particular length of time, whether all of the plurality of power supplies are outputting a same voltage; determining, when the plurality of power supplies are outputting the same voltage, whether the second voltage has been reached; and instructing, when the second voltage has not been reached, the power module to ramp up the output voltage by another step voltage. 13. The method of claim 12 , further comprising: identifying, when all of the plurality of power supplies are not outputting the same voltage, a power supply, of the plurality of power supplies, associated with an output voltage that is less than an output voltage associated with another power supply of the plurality of power supplies; and ramping up the output voltage of the identified power supply to match an output voltage associated with at least one other power supply of the plurality of power supplies. 14. The method of claim 10 , further comprising: polling, when the power module is outputting the second voltage, the plurality of power supplies at particular intervals to determine whether all of the pluralit