Fluid pumping systems, devices and methods

We claim: 1. A diaphragm configured for use in a reciprocating positive-displacement pump, the diaphragm configured to be interposed between a hemispheroid pumping chamber wall and a hemispheroid actuation chamber wall, which together define a spheroid chamber, thereby separating the spheroid chamber into a pumping chamber defined by the diaphragm and the hemispheroid pumping chamber wall and an actuation chamber defined by the membrane and the hemispheroid actuation chamber wall, the actuation chamber being configured to receive a control gas for pneumatically actuating the diaphragm to operate the pump, wherein the diaphragm comprises: a pre-formed hemispheroid membrane having a circular rim integral to the membrane and a dome-shaped portion of the membrane, wherein the dome-shape portion of the membrane has a variable thickness; a smooth surface on a first side of the dome-shape portion of the membrane configured for facing the actuation chamber wall when assembled for use; and an arrangement of bumps, dots, ribs or bars that comprise thickened regions of the dome-shaped portion of the membrane that stand above the surrounding surface on a second side of the dome-shaped portion of the membrane configured for facing the pumping chamber of the pump when assembled for use; wherein the bumps, dots, ribs or bars are arranged to create spaces that prevent pockets of fluid from being caught and provide open passages for fluid flow from a periphery of the pumping chamber to an outlet of the pumping chamber even when a volume of the pumping chamber is at a minimum; and wherein the diaphragm is made from flexible materials and configured to reciprocate from a position contacting the pump chamber wall to a position contacting the actuation chamber wall during a draw stroke of the pump and from the position contacting the actuation chamber wall to the position contacting the pump chamber wall during a delivery stroke of the pump. 2. The diaphragm according to claim 1 , wherein the thickened regions of the dome-shaped portion of the membrane that stand above the surrounding surface comprise raised bumps. 3. The diaphragm according to claim 1 , wherein the circular rim and the dome-shaped portion of the membrane are made from silicone. 4. The diaphragm according to claim 1 , wherein the circular rim is thicker than the dome-shape portion of the membrane. 5. The diaphragm according to claim 1 , wherein the thickened regions of the dome-shape portion of the membrane that stand above the surrounding surface grooves are spaced away from the circular rim such that the membrane lacks bumps in the area near the circular rim. 6. The diaphragm according to claim 5 , wherein the thickened regions of the dome-shape portion of the membrane that stand above the surrounding surface grooves are distributed on over the second side of the dome-shape portion of the membrane, except in an area adjacent to and near the circular rim. 7. A reciprocating positive-displacement pump for pumping a fluid, the positive-displacement pump comprising: a rigid bottom plate including a hemispheroid pumping chamber wall; a rigid top plate including a hemispheroid actuation chamber wall with a pneumatic port; a rigid middle plate; and a first diaphragm comprising a pre-formed hemispheroid membrane and a thickened rim integral to the membrane, wherein the top plate and bottom plate are joined to the middle plate, with the hemispheroid pumping chamber wall aligned with the hemispheroid actuation chamber wall to form a spheroid first central cavity, and wherein a groove surrounding a perimeter of the hemispheroid actuation chamber wall is formed between the middle plate and the top plate; wherein the thickened rim of the first diaphragm is held in the groove so as to separate the first central cavity into a pumping chamber for receiving a fluid to be pumped, wherein the pumping chamber is defined by the first diaphragm and the hemispheroid pumping chamber wall and an actuation chamber for receiving a control gas for pneumatically actuating the pump, wherein the actuation chamber is defined by the first diaphragm and the hemispheroid actuation chamber wall, and wherein an inlet and an outlet of the pumping chamber are formed between the bottom plate and the middle plate. 8. The reciprocating positive-displacement pump according to claim 7 , wherein the hemispheroid pumping chamber wall and the hemispheroid actuation chamber wall are aligned with an opening in the middle plate to form the first central cavity. 9. The reciprocating positive-displacement pump according to claim 7 , further including an actuation system that is configured to intermittently provide either a positive or a negative pressure to the actuation chamber; and wherein the actuation system includes: a reservoir containing a control fluid at either a positive or a negative pressure, and a valving mechanism for controlling a flow of control fluid between the actuation chamber and the reservoir. 10. The reciprocating positive-displacement pump according to claim 9 , wherein the valving mechanism includes a binary on-off valve. 11. The reciprocating positive-displacement pump according to claim 9 , further including: an actuation-chamber pressure transducer for measuring the pressure of the actuation chamber; and a controller configured to receive pressure information from the actuation-chamber pressure transducer and controls the valving mechanism. 12. The reciprocating positive-displacement pump according to claim 9 , wherein: the controller is configured to cause dithering of the valving mechanism and to determine when a stroke ends from pressure information from the actuation-chamber pressure transducer, and wherein the controller is configured to control the valving mechanism to cause the membrane of the first diaphragm or the second diaphragm to reach the hemispheroid actuation chamber wall at a beginning of each stroke, and to reach a valve seat at an end of each stroke, wherein the controller is configured to determine the amount of flow through the pump based on a number of strokes. 13. The reciprocating positive-displacement pump according to claim 9 , wherein: the controller is configured to integrate pressure information from the actuation-chamber pressure transducer over time during a stroke to detect an aberrant flow condition. 14. The reciprocating positive-displacement pump according to claim 9 , wherein, the positive-displacement pump or pod pump cassette further includes: a reservoir pressure transducer for measuring a pressure of gas in the reservoir, wherein the controller is configured to receive pressure information from the reservoir pressure transducer, and wherein the controller is configured to compare the pressure information from the actuation-chamber and reservoir pressure transducers to determine whether either of the pressure transducers are malfunctioning. 15. The reciprocating positive-displacement pump according to claim 9 , further including an actuation system that is configured to alternately provide positive and negative pressure to the actuation chamber. 16. The reciprocating positive-displacement pump according to claim 15 , wherein the actuation system includes: a positive-pressure reservoir; a negative-pressure reservoir; and a valving mechanism for controlling the flow of control fluid between the actuation chamber and each of the reservoirs. 17. A pump cassette comprising the reciprocating positive-displacement pump according to claim 7 ; wherein the bottom plate further comprises a second hemispheroid pumpin