Carbonator

What is claimed is: 1. A carbonation device having a microprocessor, the device adapted to carbonate contents of a bottle containing a liquid, the bottle having a maximum fill level, comprising: a delivery valve adapted to be attached to a carbon dioxide cylinder, the delivery valve having a valve actuator; the delivery valve supplying carbon dioxide from the cylinder to a fill head, the fill head being connected to a fill line from the delivery valve and to a vent that is controlled by an exhaust solenoid valve; the fill head having a pressure sensor that provides a pressure signal to the microprocessor, the pressure sensor located above the maximum fill level of the bottle when the bottle is in a sealed engagement with the fill head; and wherein the microprocessor is adapted to operate the valve actuator in multiple discrete increments, each increment resulting in an increase in pressure over a period of time, as measured by the pressure sensor and the microprocessor; and wherein the microprocessor is further adapted to cooperate with the pressure sensor to determine a first rate of a pressure increase during a first increment, a second rate of pressure increase during a second increment, and perform a comparison of the first rate to the second rate and, based on a rate decrease, to determine an amount of carbon dioxide remaining in the cylinder. 2. The device of claim 1 , wherein: the exhaust solenoid valve remains closed as carbon dioxide is being supplied to the fill head until an upper pressure limit is reached, the upper pressure limit being measured by the microprocessor using the pressure sensor. 3. The device of claim 2 , wherein: each increment having predetermined upper and lower pressure limits and thus defining a pressure curve over time; the microprocessor summing an integral of the pressure curve to determine a total delivered pressurization. 4. The device of claim 3 , wherein: the lower pressure limit for an increment is equal to or greater than 40 psi. 5. The device of claim 3 , wherein: an increment is followed by a predetermined rest interval. 6. The device of claim 3 , wherein: the exhaust solenoid valve is activated between increments. 7. The device of claim 1 , wherein: the controller receives a temperature input signal that relates to a temperature of the contents; the controller increasing a delivery volume of carbon dioxide when the temperature of the contents is below a room temperature. 8. The device of claim 1 , wherein: the reduction in the carbon dioxide volume in the cylinder is displayed on a user interface of the device. 9. The device of claim 1 , wherein: the exhaust solenoid valve remains closed as carbon dioxide is being supplied to the fill head until an upper pressure limit is reached, the upper pressure limit being measured by the controller using the pressure sensor; each increment having predetermined upper and lower pressure limits thus defining a pressure curve over time; the microprocessor arranged to sum an integral of the pressure curve to determine a total delivered carbonation; the exhaust solenoid valve being activated between increments; and wherein the vent is operated by the microprocessor to close when the lower pressure limit is reached. 10. A carbonation device, comprising: a microprocessor, the device adapted to carbonate the contents of a bottle containing a liquid, the bottle having a maximum fill level, the device further comprising: a carbonation delivery valve adapted to be attached to a carbon dioxide cylinder, the delivery valve having a valve actuator; the delivery valve supplying carbon dioxide to a fill head, the fill head being connected to a fill line from the delivery valve and to a vent that is controlled by an exhaust solenoid valve; the fill head having a pressure sensor that provides a pressure signal to the microprocessor, the pressure sensor located above the maximum fill level of the bottle when the bottle is in a sealed engagement with the fill head; wherein the exhaust solenoid valve remains closed as carbon dioxide is being supplied to the fill head until an upper pressure limit is reached, the upper pressure limit being measured by the controller using the pressure sensor; the valve actuator operated by the microprocessor in multiple discrete increments; wherein the microprocessor is further adapted to cooperate with the pressure sensor to determine a first rate of a pressure increase during a first increment, a second rate of pressure increase during a second increment, and perform a comparison of the first rate to the second rate and, based on a rate decrease, to determine an amount of carbon dioxide remaining in the cylinder; and each increment having predetermined upper and lower pressure limits and thus defining a pressure curve over time; the microprocessor summing an integral of the pressure curve to determine a total delivered carbonation; the exhaust solenoid valve being activated between increments; and wherein the vent is operated by the microprocessor to close when the lower pressure limit is reached. 11. The device of claim 10 , wherein: a rest interval comes after the vent is closed.