Occlusion detection techniques for a fluid infusion device having a rotary pump mechanism and sensor contact elements

What is claimed is: 1. A fluid pump mechanism comprising: a stator comprising a fluid chamber defined therein, and further comprising a stator cam element having a stator cam surface; a rotor comprising: an endcap having a reference surface; an axial extension section protruding from the endcap, wherein at least a portion of the axial extension section fits inside the fluid chamber; and a rotor cam element having a variable height rising from the reference surface, the rotor cam element cooperating with the stator cam element to axially displace the rotor, relative to the stator, as a function of angular position of the rotor; an electrically conductive sensor contact element on the reference surface and located in an area that is unoccupied by the rotor cam element; and an electrically conductive sensing element terminating at or near the stator cam surface, the electrically conductive sensing element cooperating with a detection circuit to detect whether or not the electrically conductive sensing element is in physical and electrical contact with the electrically conductive sensor contact element; wherein the detection circuit monitors characteristics of a detection signal obtained from the electrically conductive sensing element in response to angular position of the rotor to determine an operating condition of the fluid pump mechanism. 2. The fluid pump mechanism of claim 1 , wherein: the electrically conductive sensor contact element comprises an electrically conductive trace; and the electrically conductive sensing element comprises a first electrically conductive lead having a first end exposed at the stator cam surface, and having a second end coupled to the detection circuit, and a second electrically conductive lead having a first end exposed at the stator cam surface, and having a second end coupled to the detection circuit. 3. The fluid pump mechanism of claim 1 , further comprising a biasing element that provides a biasing force to urge the rotor cam element toward the stator cam element and the reference surface. 4. The fluid pump mechanism of claim 3 , wherein, under normal operating conditions: a complete rotation of the rotor corresponds to one pumping cycle comprising a fluid intake period and a fluid expulsion period; during the fluid intake period, the stator cam element is in contact with the rotor cam element; during the fluid expulsion period, the rotor cam element disengages the stator cam element, and the biasing element axially displaces the rotor such that the rotor cam element moves toward the reference surface; and after the fluid expulsion period and before a next fluid intake period, the electrically conductive sensing element is in physical and electrical contact with the electrically conductive sensor contact element. 5. The fluid pump mechanism of claim 4 , wherein, under downstream occlusion conditions: fluid pressure caused by an occlusion downstream of the fluid pump mechanism prevents the electrically conductive sensing element from contacting the electrically conductive sensor contact element after the fluid expulsion period; and the detection circuit determines the presence of a downstream occlusion in response to the detection signal obtained under the downstream occlusion conditions. 6. The fluid pump mechanism of claim 1 , wherein: the detection signal obtained from the electrically conductive sensing element is a binary signal having a first logical state and a second logical state; the first logical state corresponds to physical and electrical contact between the electrically conductive sensing element and the electrically conductive sensor contact element; the second state corresponds to non-contact between the electrically conductive sensing element and the electrically conductive sensor contact element; a first binary pattern of the detection signal obtained during one rotation of the rotor is indicative of normal and expected operation of the fluid pump mechanism; and a second binary pattern of the detection signal during one rotation of the rotor is indicative of a fault condition of the fluid pump mechanism. 7. The fluid pump mechanism of claim 6 , wherein: the detection circuit initiates an alert, alarm, or warning message in response to detecting the second binary pattern. 8. The fluid pump mechanism of claim 6 , wherein: the detection circuit initiates an alert, alarm, or warning message in response to detecting the second binary pattern during a plurality of consecutive rotations of the rotor. 9. The fluid pump mechanism of claim 6 , wherein the fault condition is a downstream occlusion condition. 10. The fluid pump mechanism of claim 1 , further comprising: an inlet valve that opens and closes as a function of angular and axial position of the rotor relative to the stator; and an outlet valve that opens and closes as a function of angular and axial position of the rotor relative to the stator; wherein the electrically conductive sensor contact element is located in an area on the reference surface corresponding to a valve state in which the inlet valve is closed and the outlet valve is open. 11. The fluid pump mechanism of claim 1 , further comprising: an inlet valve that opens and closes as a function of angular and axial position of the rotor relative to the stator; and an outlet valve that opens and closes as a function of angular and axial position of the rotor relative to the stator; wherein the electrically conductive sensor contact element is located in an area on the reference surface corresponding to a valve state in which the inlet valve is closed and the outlet valve is closed. 12. The fluid pump mechanism of claim 1 , further comprising an inlet valve that opens and closes as a function of angular and axial position of the rotor relative to the stator, and an outlet valve that opens and closes as a function of angular and axial position of the rotor relative to the stator, the rotor cam element disengaging the stator cam element when both the inlet valve and the outlet valve are closed, and the electrically conductive sensor contact element is located on an area of the reference surface such that, under normal operating conditions, the electrically conductive sensing element makes no physical or electrical contact with the electrically conductive sensor contact element. 13. The fluid pump mechanism of claim 12 , wherein the electrically conductive sensor contact element is located on the area of the reference surface such that, under upstream occlusion conditions, the electrically conductive sensing element physically and electrically contacts the electrically conductive sensor contact element after the rotor cam element disengages the stator cam element, when the inlet valve is closed, and when the outlet valve is closed. 14. The fluid pump mechanism of claim 13 , wherein, under upstream occlusion conditions: vacuum conditions created by an occlusion upstream of the fluid pump mechanism allow the rotor cam element to move toward the reference surface even though the outlet valve is closed; and the detection circuit determines that an upstream occlusion has occurred in response to the electrically conductive sensing element physically and electrically contacting the electrically conductive sensor contact element. 15. The fluid pump mechanism of claim 12 , further comprising an electrically conductive trailing sensor contact element on the reference surface and located in a region that is unoccupied by the rotor cam element, wherein, under normal operating conditions, the electrically conductive sensing eleme