Occlusion detection techniques for a fluid infusion device having a rotary pump mechanism and an optical sensor

What is claimed is: 1. A fluid pump mechanism comprising: a stator comprising a rotor chamber and a stator cam element having a stator cam surface; and a rotor comprising an endcap and an axial extension section protruding from the endcap, the axial extension section shaped and sized for insertion into the rotor chamber of the stator, and the rotor further comprising an optically detectable tab located around an outer exposed surface of the endcap, a reference surface, 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; the rotor further comprising a conical tapered section having an asymmetrical profile, the conical tapered section located between the endcap and the axial extension section to remain exposed during operation of the fluid pump mechanism; wherein the optically detectable tab rotates and axially translates as a function of angular position of the rotor; and wherein an optical detection circuit interrogates the outer exposed surface of the endcap to detect the optically detectable tab once per revolution of the rotor, and interrogates the conical tapered section during operation of the fluid pump mechanism to determine an operating condition of the fluid pump mechanism based on a detected width of an interrogated location of the conical tapered section. 2. The fluid pump mechanism of claim 1 , 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 each pumping cycle, the optically detectable feature axially translates in accordance with a first characteristic movement; and the optical detection circuit observes the first characteristic movement to determine that the operating condition of the fluid pump mechanism is normal. 3. The fluid pump mechanism of claim 2 , wherein, under downstream occlusion conditions: a complete rotation of the rotor corresponds to one occluded pumping cycle; during each occluded pumping cycle, the optically detectable feature axially translates in accordance with a second characteristic movement that is optically distinguishable from the first characteristic movement; and the optical detection circuit observes the second characteristic movement to determine that the operating condition of the fluid pump mechanism corresponds to a downstream occlusion. 4. The fluid pump mechanism of claim 3 , wherein, under normal operating conditions: one pumping cycle comprises 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 a 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 rotor cam element is in contact with the reference surface. 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 rotor cam element from contacting the reference surface after the fluid expulsion period. 6. A fluid infusion device for delivering a medication fluid to a body, the fluid infusion device comprising: a fluid pump mechanism that cooperates with a fluid cartridge module, the fluid pump mechanism comprising: a rotor and a stator, the stator comprising a rotor chamber and a stator cam element having a stator cam surface, the rotor comprising an endcap and an axial extension section protruding from the endcap, the axial extension section shaped and sized for insertion into the rotor chamber of the stator; the rotor further comprising an optically detectable tab located around an outer exposed surface of the endcap, a reference surface, and a rotor cam element having a variable height rising from the reference surface, wherein the optically detectable tab rotates and axially translates as a function of angular position of the rotor; 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; wherein the rotor further comprises a conical tapered section having an asymmetrical profile, the conical tapered section located between the endcap and the axial extension section to remain exposed during operation of the fluid pump mechanism; a biasing element that provides a biasing force to urge the rotor cam element toward the stator cam element and toward the reference surface; a subcutaneous conduit in fluid communication with an outlet valve of the fluid pump mechanism; a drive motor coupled to actuate the rotor of the fluid pump mechanism to pump medication fluid from the fluid cartridge module to the body, via the subcutaneous conduit; and an optical detection circuit to interrogate the outer exposed surface of the endcap to detect the optically detectable tab once per revolution of the rotor, and to interrogate the conical tapered section during operation of the fluid pump mechanism to determine an operating condition of the fluid pump mechanism based on a detected width of an interrogated location of the conical tapered section. 7. The fluid infusion device of claim 6 , wherein: the fluid infusion device is a disposable insulin pump device; and the medication fluid comprises insulin. 8. The fluid infusion device of claim 6 , 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 each pumping cycle, the optically detectable feature axially translates in accordance with a first characteristic movement; and the optical detection circuit observes the first characteristic movement to determine that the operating condition of the fluid pump mechanism is normal. 9. The fluid infusion device of claim 8 , wherein, under downstream occlusion conditions: a complete rotation of the rotor corresponds to one occluded pumping cycle; during each occluded pumping cycle, the optically detectable feature axially translates in accordance with a second characteristic movement that is optically distinguishable from the first characteristic movement; and the optical detection circuit observes the second characteristic movement to determine that the operating condition of the fluid pump mechanism corresponds to a downstream occlusion.