Estimating a departure time for a plug-in electric vehicle

What is claimed is: 1. A method comprising: analyzing, by a control device, power meter data to determine that a connector of the control device is coupled to an inlet of a Plug-in Electric Vehicle (“PEV”), wherein the connector being coupled to the inlet causes a charger of the PEV to be operable to charge a battery set included in the PEV with electricity and the power meter data describes one or more readings of a power meter and the one or more readings describe a unique electrical characteristic of the PEV that indicates whether the connector is coupled to the inlet; charging the battery set with electricity via a power coupling formed by the connector being coupled to the inlet, wherein the charging occurs responsive to a determination that the connector is coupled to the inlet based on a presence of the unique electrical characteristic of the PEV being identified by the analysis of the power meter data; retrieving clock data from a non-transitory memory, wherein the clock data describes time information associated with a present day when the connector of the control device is coupled to the inlet of the PEV; determining a next day of a next journey for the PEV based on the clock data and a category of the next day; retrieving history data associated with the category of the next day, wherein the history data describes a habitual time when the connector and the inlet are decoupled for a plurality of historical days within the category of the next day; and estimating that a departure time for the next journey is substantially equal to the habitual time when the connector and the inlet are decoupled for the historical days within the category of the next day. 2. The method of claim 1 , wherein the history data describes a historical pattern of times when the connector and the inlet were decoupled for historical days within the category of the next day and the habitual time is indicated by the historical pattern. 3. The method of claim 1 , wherein the category of the next day is selected from a set of categories that includes: Monday; Tuesday; Wednesday; Thursday; Friday; Saturday; and Sunday. 4. The method of claim 1 , wherein the category of the next day is selected from a set of categories that includes: Weekday; and Weekend day. 5. The method of claim 1 , wherein the category of the next day is selected from a set of categories that includes a list of holidays for a geographic region where the PEV is located so that if the next day is a specific holiday then the category selected from the set includes a plurality of historical days that occurred on the specific holiday. 6. The method of claim 5 , wherein the clock data describes whether the next day is a holiday and an identifier for the specific holiday. 7. The method of claim 1 , wherein the clock data describes a present day of a week. 8. The method of claim 1 , wherein the power meter data describes one or more of the following: an increased current that indicates that the connector is coupled to the inlet; and an increased load that indicates that the connector is coupled to the inlet. 9. The method of claim 1 , wherein coupling the connector to the inlet triggers a signature response that is detectable in electricity transmitted via the power coupling shared between the control device and the inlet, wherein the power coupling is monitored by the control device using the power meter that records the power meter data describing the electricity transmitted via the power coupling, and the control device determines that the connector of the control device is coupled to the inlet of the PEV based on identifying a presence of the signature response in the power meter data, wherein the signature response includes the unique electrical characteristic described by the power meter data. 10. The method of claim 1 , wherein the unique electrical characteristic of the PEV is a characteristic of a charging circuit included in the PEV. 11. The method of claim 1 , further comprising: retrieving a charge schedule from the non-transitory memory, wherein the charge schedule describes a plurality of slots of time that are available for charging the battery set; and selecting a time slot from the plurality of time slots based on the estimated departure time so that the selected time slot occurs prior to the estimated departure time. 12. The method of claim 11 , further comprising: determining that the connector is decoupled from the inlet based on the power meter data describing an electronical condition that is consistent with a decoupling; receiving new clock data that describes a time when the connector was decoupled from the inlet and a category for the present day when the connector was decoupled from the inlet; building new history data that describes the time and the category; and storing the new history data in the non-transitory memory so that it is associated with other historical days that have the same category. 13. The method of claim 1 , further comprising: retrieving a charge schedule and Time-of-Use data (“TOU data”) from the non-transitory memory, wherein the charge schedule describes a plurality of slots of time that are available for charging the battery set and the TOU data describes a plurality of future time periods and one or more prices for electricity during each of the plurality of future time periods; and selecting a time slot from the plurality of time slots based on the estimated departure time and the TOU data so that the selected time slot occurs prior to the estimated departure time and is optimized to charge the battery set at a substantially minimum price. 14. The method of claim 1 , further comprising: identifying a route for the next journey; determining an amount of charge needed in the battery set for the PEV to complete the route; retrieving a charge schedule and Time-of-Use data (“TOU data”) from the non-transitory memory, wherein the charge schedule describes a plurality of slots of time that are available for charging the battery set and the TOU data describes a plurality of future time periods and one or more prices for electricity during each of the plurality of future time periods; and selecting one or more time slots from the plurality of time slots based on the estimated departure time, the TOU data and the amount of charge needed in the battery set, wherein the one or more time slots are selected so that, at the departure time and for a substantially minimized price, the battery set will store at a minimum the amount of charge needed in the battery set for the PEV to complete the route. 15. A computer program product comprising a non-transitory computer-usable medium including a computer-readable program, wherein the computer-readable program when executed on a computer causes the computer to: analyze, by a processor of the computer, power meter data to determine that a connector of a control device is coupled to an inlet of a Plug-in Electric Vehicle (“PEV”), wherein the connector being coupled to the inlet causes a charger of the PEV to be operable to charge a battery set included in the PEV with electricity and the power meter data describes one or more readings of a power meter that describe a unique electrical characteristic of the PEV that indicates whether the connector is coupled to the inlet; charge the battery set with electricity via a power coupling formed by the connector being coupled to the inlet, wherein the charging occurs responsive to a determination that the connector is coupled to the inlet based on a presence of the unique electrical characteristic of the PEV being identified by the analysis of