Oil pan having small active volume oil reservoir and methods of using the same

The invention claimed is: 1. An oil reservoir comprising: an upper sump defined by a sump bottom and one or more side walls, and including an at least partially open top end capable of receiving oil; a lower sump disposed vertically below the upper sump including a top end contiguous with at least a portion of the upper sump bottom; a valve-controlled orifice penetrating the upper sump bottom and including an actuatable waste gate capable of communicating oil collected in the upper sump to the lower sump; an oil chimney having an inlet end capable of receiving oil and a discharge end in fluid communication with the lower sump and capable of providing oil thereto; a drip tray disposed above the upper sump and configured to receive oil and communicate at least a portion of the collected oil to the inlet end of the oil chimney, and an oil pump conduit having an inlet end disposed within the lower sump, and capable of extracting oil therefrom, wherein the actuatable wastegate is actuated to communicate oil collected in the upper sump to the lower sump in response to an increased oil demand event, an end of an ICE oil circulation system warmup duration, and/or the temperature of oil in the lower sump exceeding a minimum temperature threshold. 2. The oil reservoir of claim 1 , further comprising a drip tray disposed proximate the open top end of the upper sump and at least partially between the open top end and the upper sump bottom, wherein the drip tray is capable of collecting at least a portion of oil communicated to the upper sump open top end and further capable of communicating the collected oil to the oil chimney. 3. The oil reservoir of claim 2 , further comprising a windage tray disposed above the drip tray relative to the upper sump, and capable of communicating oil to the drip tray. 4. The oil reservoir of claim 1 , wherein the upper sump bottom further includes a bleed hole capable of establishing fluid communication between the upper sump and the lower sump. 5. The oil reservoir of claim 1 , wherein the lower sump has a smaller fluid capacity than the upper sump. 6. An internal combustion engine (ICE) oil circulation system, comprising: an ICE capable of receiving and discharging oil; and an oil reservoir including: an upper sump defined by a sump bottom and one or more side walls, and including an at least partially open top end capable of receiving oil from the ICE; a lower sump disposed vertically below the upper sump including a top end contiguous with at least a portion of the upper sump bottom; a valve-controlled orifice penetrating the upper sump bottom and including an actuatable wastegate capable of communicating oil collected in the upper sump to the lower sump; an oil chimney having an inlet end capable of receiving oil and a discharge end in fluid communication with the lower sump, and capable of providing oil thereto; a drip tray disposed above the upper sump and configured to receive oil and communicate at least a portion of the collected oil to the inlet end of the oil chimney; and an oil pump conduit having an inlet end disposed within the lower sump, and configured to extract oil from the lower sump and communicate the same to the ICE; wherein the actuatable wastegate is actuated to communicate oil collected in the upper sump to the lower sump in response to an increased oil demand event, an end of an ICE oil circulation system warmup duration, and/or the temperature of oil in the lower sump exceeding a minimum temperature threshold. 7. The ICE oil circulation system of claim 6 , further comprising a drip tray disposed proximate the open top end of the upper sump and at least partially between the open top end and the supper sump bottom, wherein the drip tray is capable of collecting at least a portion of oil communicated to the oil reservoir proximate the upper sump open top end and further capable of communicating the collected oil to the oil chimney. 8. The ICE oil circulation system of claim 7 , further comprising a windage tray disposed above the drip tray relative to the upper sump, and capable of communicating oil to the drip tray. 9. The ICE oil circulation system of claim 6 , wherein the upper sump bottom further includes a bleed hole capable of establishing fluid communication between the upper sump and the lower sump. 10. The ICE oil circulation system of claim 6 , wherein one of more of the drip tray or oil reservoir is angled such that at least a portion of the oil collected by the drip tray is directed to the oil chimney by virtue of gravity. 11. A method for operating an internal combustion engine (ICE) oil circulation system, wherein the system includes an ICE capable of receiving and discharging oil, and an oil reservoir including an upper sump defined by a sump bottom and one or more side walls and including an at least partially open top end capable of receiving oil from the ICE, a lower sump disposed vertically below the upper sump including a top end contiguous with at least a portion of the upper sump bottom, a valve-controlled orifice penetrating the upper sump bottom and including an actuatable wastegate capable of communicating oil collected in the upper sump to the lower sump by actuating to and/or between one or more of an open position and a closed position, an oil chimney having an inlet end capable of receiving oil and a discharge end in fluid communication with the lower sump and capable of providing oil thereto, a drip tray disposed above the upper sump and configured to receive oil and communicate at least a portion of the collected oil to the inlet end of the oil chimney, and an oil pump conduit having an inlet end disposed within the lower sump and configured to extract oil from the lower sump and communicate the same to the ICE, wherein the actuatable wastegate is actuated to communicate oil collected in the upper sump to the lower sump in response to an increased oil demand event, an end of an ICE oil circulation system warmup duration, and/or the temperature of oil in the lower sump exceeding a minimum temperature threshold, the method comprising: maintaining the valve-controlled orifice in an at least partially open position for a draw down duration temporally proximate an ICE cold start event, wherein at least a portion of the draw down duration occurs after the cold start event; circulating oil between the ICE and the oil reservoir via the oil pipe conduit after the ICE cold start event; actuating the valve-controlled orifice to a substantially closed position subsequent to the draw down duration for a warmup duration; and actuating the valve-controlled orifice to an at least partially open position subsequent to the warmup duration. 12. The method of claim 11 , wherein the draw down duration comprises a period of time sufficient to allow a rate of oil transfer from the ICE to the lower sump via the oil chimney to achieve a rate substantially equal to a rate of oil extraction from the lower sump via the oil pipe conduit. 13. The method of claim 12 , wherein the rate of oil extraction from the lower sump via the oil pipe conduit comprises an average rate measured over a period of time. 14. The method of claim 11 , wherein the draw down duration expires after the oil achieves a minimum temperature and/or viscosity threshold. 15. The method of claim 11 , wherein the warmup duration expires after the oil achieves a minimum temperature and/or viscosity threshold. 16. The method of claim 11 , wherein maintaining the valve-controlled orifice in an at least partially open position further comprises actuating the valve-controlled orifice from a substan