Direct control for variable displacement pumps using a bypass valve and a minimum pressure shutoff valve

What is claimed is: 1. A system comprising: a variable displacement pump (VDP) in fluid communication with an inlet line and with an outlet line, wherein the VDP includes a variable displacement mechanism configured to vary pressure to the outlet line; a bypass valve (BPV) including a BPV inlet in fluid communication with the outlet line, and a BPV outlet in fluid communication with a bypass line that feeds into the inlet line upstream of the VDP; a minimum pressure shutoff valve (MPSOV) connected in fluid communication with the outlet line, configured to block flow through the outlet line for shutoff, wherein the MPSOV is connected in fluid communication with the BPV for triggering recirculation through the BPV; an actuator operatively connected to control the BPV to vary flow from the BPV inlet to the bypass line; a flow sensing valve (FSV) connected in the outlet line, wherein the FSV includes a sensor configured to generate sensor data indicative of flow out of the outlet line; and a controller operatively connected to the actuator to control recirculation flow passed through the BPV based on the sensor data and based on a predetermined low threshold of flow through the VDP. 2. The system as recited in claim 1 , wherein the BPV includes no outlets other than the BPV outlet so all flow through the BPV is supplied to the BPV outlet. 3. The system as recited in claim 1 , wherein the controller is configured to: control the BPV to maintain a baseline flow through the BPV under a first condition wherein requested flow from a downstream system is above the predetermined low threshold, and control the BPV to increase the flow through the BPV above the baseline flow for a second flow condition wherein requested flow from the downstream system is at or below the predetermined low threshold. 4. The system as recited in claim 3 , further comprising: a first electrohydraulic servo valve (EHSV) connected in fluid communication with the BPV by a first control line, wherein the first EHSV is connected in fluid communication with both the inlet line and with the outlet line through respective connection lines, and wherein the first EHSV is operatively connected to the controller for active control of the first EHSV to actuate the BPV; a first MPSOV line connecting the MPSOV to the first control line for fluid communication; a second MPSOV line connecting the MPSOV to the inlet line for fluid communication; an MPSOV control line that connects the MPSOV in fluid communication with the inlet line through a fixed throttle; and a solenoid valve (SOL) connected in fluid communication with the outlet line and with the MPSOV control line for actuating the MPSOV between first and second states, wherein the MPSOV includes an MPSOV valve member with a first position in the MPOV that connects the first and second MPSOV lines in fluid communication and blocks flow through the outlet line, and a second position that blocks fluid communication of the first and second MPSOV lines and allows flow though the outlet line. 5. The system as recited in claim 4 , wherein a first position sensor is operatively connected to the BPV to provide sensor output indicative of position of a valve member of the BPV, wherein the first position sensor is operatively connected to the controller to provide feedback for controlling the BPV. 6. The system as recited in claim 5 , further comprising a second EHSV connected in fluid communication with the variable displacement mechanism by a second control line for control of flow through the VDP, wherein the second EHSV is connected in fluid communication with both the inlet line and with the outlet line through respective connection lines, and wherein the second EHSV is operatively connected to the controller for active control of the second EHSV to actuate the variable displacement mechanism. 7. The system as recited in claim 6 , wherein a second position sensor is operatively connected to the variable displacement mechanism to provide sensor output indicative of position of the variable displacement mechanism, wherein the second position sensor is operatively connected to the controller to provide feedback for controlling the variable displacement mechanism. 8. The system as recited in claim 7 , further comprising a pressure sensor operatively connected to the outlet line to generate sensor output indicative of pressure in the outlet line, wherein the pressure sensor is operatively connected to the controller for active control of the variable displacement mechanism and/or of the BPV based on pressure in the outlet line. 9. The system as recited in claim 8 , wherein the sensor output is indicative of flow demanded by the downstream system supplied by the outlet line, and wherein the controller is configured to control position of the valve member of the BPV to maintain bypass flow through the BPV in the second condition wherein the controller governs the bypass flow through the BPV according to B ⁢ F = P ⁢ F - DSFD wherein BF is flow through the BPV, PF is flow through the VDP, and DSFD is flow demanded by the downstream system supplied by the outlet line as indicated by the sensor output. 10. The system as recited in claim 1 , wherein the FSV includes an FSV inlet, an FSV outlet, and a valve member, wherein a biasing member biases the valve member in a first direction, and wherein pressure of flow through the FSV from the FSV inlet to the FSV outlet biases the valve member in a second direction opposite the first direction. 11. The system as recited in claim 10 , wherein the sensor includes a position sensor operatively connected to monitor position of the valve member in the FSV to generate the sensor data. 12. The system as recited in claim 11 , wherein the FSV includes a pressure port on a side of the valve member opposite from the FSV inlet and the FSV outlet, wherein a pressure line connects the FSV outlet in fluid communication with the pressure port. 13. The system as recited in claim 12 , further comprising: a BPV control line connecting the BPV in fluid communication with the inlet line through a first fixed throttle; a first MPSOV line connecting the MPSOV in fluid communication with the BPV control line; a second MPSOV line connecting the MPSOV to the outlet line for fluid communication; an MPSOV control line that connects the MPSOV in fluid communication with the inlet line through a fixed throttle; and a solenoid valve (SOL) connected in fluid communication with the outlet line and with the MPSOV control line for actuating the MPSOV between first and second states, wherein the MPSOV includes an MPSOV valve member with a first position in the MPOV that disconnects the first and second MPSOV lines from being in fluid communication and blocks flow through the outlet line, and a second position that connects the first and second MPSOV lines in fluid communication and allows flow though the outlet line. 14. A method comprising: receiving sensor feedback from a flow sensing valve (FSV) indicative of flow demanded by a downstream system supplied from an outlet line of a variable displacement pump (VDP); controlling, by an actuator, a bypass valve (BPV) to vary flow from a BPV inlet to a bypass line; fluidically communicating, by an MPSOV, with the