Systems and methods for monitoring reduced pressure supplied by a disc pump system

We claim: 1. A disc pump system comprising: a pump body having a substantially cylindrical shape defining a cavity for containing a fluid, the cavity being formed by a side wall closed at both ends by substantially circular end walls, at least one of the end walls being a driven end wall having a central portion and a peripheral portion extending radially outwardly from the central portion of the driven end wall; an actuator operatively associated with the central portion of the driven end wall to cause an oscillatory motion of the driven end wall thereby generating displacement oscillations of the driven end wall in a direction substantially perpendicular thereto; an isolator positioned between the peripheral portion of the driven end wall and the side wall to reduce dampening of the displacement oscillations, the isolator comprising a flexible material that stretches and contracts in response to the oscillatory motion of the driven end wall; a first aperture disposed in either one of the end walls and extending through the pump body; a second aperture disposed in the pump body and extending through the pump body; a valve disposed in at least one of the first aperture and second aperture; a strain gauge operatively associated with the flexible material of the isolator to measure the displacement oscillations of the driven end wall for determining a change in pressure across the actuator; and a processor electrically coupled to the strain gauge and operable to: receive a signal from the strain gauge, the signal being indicative of the change in electrical resistance of the strain gauge, determine the displacement of the driven end wall at a node based on the signal received from the strain gauge, determine the average displacement of the driven end wall over a period of time and determine the pressure differential across the disc pump based on the average displacement of the driven end wall over the period of time. 2. The disc pump system of claim 1 , wherein the flexible material comprises a flexible printed circuit material. 3. The disc pump system of claim 1 , wherein the strain gauge is coupled to a circuit element of the isolator. 4. The disc pump system of claim 1 , further comprising a memory, wherein the processor is operable to generate strain gauge data based on signals received from the strain gauge and wherein the memory is operable to store the strain gauge data. 5. The disc pump system of claim 4 , wherein: the cavity of the pump body is fluidly coupled to a load via either one of the first and second apertures; the processor is operable to receive first data from the strain gauge at a first time; the processor is operable to receive second data from the strain gauge at a second time; the processor is operable to compare the first data to the second data; and the processor is operable to determine that the isolator is damaged based on the comparison of the first data to the second data. 6. The disc pump system of claim 5 , wherein the processor is operable to stop the disc pump system in response to determining that the isolator is damaged. 7. A method for measuring displacement of a driven end wall of a disc pump, the method comprising: measuring a change in the electrical resistance of a strain gauge, wherein the strain gauge is operatively associated with an isolator of the disc pump, and wherein the driven end wall comprises an actuator mounted within the disc pump on the isolator, wherein the disc pump comprises: a pump body having a substantially cylindrical shape defining a cavity for containing a fluid, the cavity being formed by a side wall closed at both ends by substantially circular end walls, at least one of the end walls being the driven end wall having a central portion and a peripheral portion extending radially outwardly from the central portion of the driven end wall; the actuator operatively associated with the central portion of the driven end wall to cause an oscillatory motion of the driven end wall thereby generating displacement oscillations of the driven end wall in a direction substantially perpendicular thereto with an annular node between the center of the driven end wall and the side wall when in use; the isolator inserted between the peripheral portion of the driven end wall and the side wall to reduce dampening of the displacement oscillations, the isolator comprising a flexible material that stretches and contracts in response to the oscillatory motion of the driven end wall; a first aperture disposed at any location in either one of the end walls other than at the annular node and extending through the pump body; a second aperture disposed at any location in the pump body other than the location of the first aperture and extending through the pump body; and a valve disposed in at least one of the first aperture and second aperture, whereby the displacement oscillations generate corresponding pressure oscillations of the fluid within the cavity of the pump body causing fluid flow through the first aperture and the second aperture when in use; communicating a signal to a processor, the signal being indicative of the change in the electrical resistance of the strain gauge; using the processor to determine the displacement of the driven end wall based on the signal; determining an average displacement of the driven end wall over a period of time; and determining pressure differential across the disc puma based on the average displacement of the driven end wall over the period of time. 8. The method of claim 7 , further comprising correlating the change in the electrical resistance of the strain gauge to the displacement of the driven end wall. 9. The method of claim 7 , farther comprising correlating the change in the electrical resistance of the strain gauge to a pressure provided to a load. 10. The method of claim 7 , wherein the flexible material comprises a flexible printed circuit material. 11. The method of claim 7 , wherein the strain gauge is coupled to a circuit element of the isolator. 12. The method of claim 7 , further comprising storing the signal in a memory. 13. The method of claim 7 , wherein the signal is a first signal, and further comprising; receiving the first signal from the strain gauge at a first time; receiving a second signal from the strain gauge at a second time; comparing the first signal to the second signal; and determining that the isolator is damaged based on the comparison of the first signal to the second signal. 14. The method of claim 13 , further comprising stopping the disc pump in response to determining that the isolator is damaged.