Methods and systems for calibration of a positional orientation between a sample container and nozzle tip

What is claimed is: 1. A method of calibrating a position of a nozzle tip relative to a sample container, comprising: providing a nozzle including a nozzle tip, the nozzle operably configured to aspirate a sample fluid from the sample container; providing a sample rack having a receptacle configured to contain the sample container during the aspirate the sample rack having a registration location; inserting a calibration target in the receptacle of the sample rack; positioning the nozzle over the calibration target at a home height location (HM); moving the nozzle downward from the home height location (HM) a distance (D) until a portion of the calibration target is sensed; positioning the nozzle over the sample rack; moving the nozzle downward until a portion of the registration location of the sample rack is sensed to determine a distance (R) from the home height location (HM) to the registration location; imaging the assembly of the sample rack and the calibration target to determine a height (H) between the registration location and a top of the calibration target in pixel space; and calculating a translation ratio (TR) between the height (H) measured in the pixel space and the height (M) measured in machine space, wherein (M) is related to distance (R) and height (H); wherein each of distance (D) and distance (R) is measured in a number of steps (S) of a stepper motor; the method further comprising: generating the translation ratio (TR) between the number of steps (S) and the height (H); and using the translation ratio (TR) to drive the nozzle tip to a predetermined drive depth (DD) in a sample container. 2. The method of calibrating of claim 1 , wherein the sensed portion of the calibration target is a bottom of a sample collection tube or small sample cup (SSC). 3. The method of calibrating of claim 1 , wherein the sensed portion of the calibration target is a top of a calibration tool. 4. The method of calibrating of claim 1 , wherein the registration location comprises a planar surface feature on the sample rack. 5. The method of calibrating of claim 1 , wherein the registration location comprises a planar surface feature on the sample rack directly proximate to the calibration target. 6. A method of calibrating a position of a nozzle tip relative to a sample container, comprising: providing a nozzle including a nozzle tip, the nozzle operably configured to aspirate a sample fluid from the sample container; providing a sample rack having a receptacle configured to contain the sample container during the aspirate the sample rack having a registration location; inserting a calibration target in the receptacle of the sample rack; positioning the nozzle over the calibration target at a home height location (HM); moving the nozzle downward from the home height location (HM) a distance (D) until a portion of the calibration target is sensed; positioning the nozzle over the sample rack; moving the nozzle downward until a portion of the registration location of the sample rack is sensed to determine a distance (R) from the home height location (HM) to the registration location; imaging the assembly of the sample rack and the calibration target to determine a height (H) between the registration location and a top of the calibration target in pixel space; and calculating a translation ratio (TR) between the height (H) measured in the pixel space and the height (M) measured in machine space, wherein (M) is related to distance (R) and height (H); the method further comprising, after calibration, imaging a sample container to determine an imaged height of the sample container, and multiplying the imaged height (IH) by the translation ratio (TR) and a factor to obtain a drive distance to drive the nozzle tip in machine space. 7. The method of calibrating of claim 1 , wherein the calibration target is a calibration tool. 8. The method of calibrating of claim 7 , wherein the calibration tool is electrically conductive, and the distance (D) is determined by sensing a conductive surface of the calibration tool. 9. The method of calibrating of claim 8 , wherein the distance (D) is determined by sensing a load of a drive motor used to drive the nozzle in a Z direction. 10. A method of calibrating a position of a nozzle relative to a sample container, comprising: providing a moveable nozzle having a nozzle tip, the moveable nozzle operably configured to aspirate a specimen; providing a sample rack having a receptacle and a registration location comprising a planar surface feature; providing a sample container inserted in the receptacle of the sample rack having a small sample cup (SSC) inserted in the sample container; positioning the nozzle over the SSC at a home position (HM); moving the nozzle downward from the home position (HM) until the nozzle tip contacts a register location comprising a bottom surface of the SSC; determining a distance (D) between the home position (HM) and the bottom surface of the SSC; imaging the planar surface feature of the sample rack and the top surface of the SSC; determining a height (H) from the planar surface feature to a top of the SSC, the height (H) determined in pixel space; and calculating a translation ratio (TR) between the height (H) measured in pixel space and a height (M) measured in machine space, wherein the height (M) is related to the distance (D) wherein the distance (D) is measured in a number of steps (S) of a stepper motor; the method further comprising: generating the translation ratio (TR) between the number of steps (S) and the height (H); and using the translation ratio (TR) to drive the nozzle tip to a predetermined drive depth (DD) in a sample container.