Motion cards provide actuation on compact blood analyser

The analyser is a comprehensive all in one design, which includes an incubator station, sample and reagent holding station, pipette assembly, centrifuge, analysis station and transport assembly. Critical areas for control were identified as the centrifuge itself plus the transport assembly that carries containers between the incubator station, centrifuge and analysis station. There is also a motion control requirement for the pipette assembly which draws and dispenses samples, reagents and dilution fluids to produce solutions for testing.

All this calls for multiple axes of coordinated motion, including single-axis point-to-point operations, multi-axis point-to-point operations and velocity controlled rotation. For a compact and cost effective solution, the designers turned to PMD motion technology, using different motion card formats and digital drives to suit the needs of different parts of the machine.

PMD’s Prodigy motion cards are available in PC-104, PCI and standalone PCB configurations. Where compact size is the primary concern, a PC-104 format can reduce overall system size by using stacked motion cards mounted on the control system mother board. On the other hand, if a more distributed architecture is needed, a standalone format (with or without on-board amplifiers) can be used to mount the motion card within the various sub-systems.

The blood analyser was well suited to individual cards and digital drives. The PMD Prodigy Machine Controller motion card was selected for the two and three axis arms in the sample storage carousel and incubator. Prodigy motion cards combine up to four amplifiers and a positioning controller on a single PCB, providing convenience and space saving as well as reduced assembly costs. The card controls the torque, velocity and position of a number of different motor types, including DC brushed, brushless and stepper motors.

Based on PMD’s industry leading Magellan motion processor, the Prodigy cards provide user-selectable profiles modes, including S-curve, trapezoidal, velocity contouring and electronic gearing. The cards accept parameters such as position, velocity, acceleration and jerk, either from the on-board C-Motion engine or from an external host to generate a corresponding trajectory on the fly. Servo loop compensation utilises a full 32-bit position resolution, and a PID loop with velocity and acceleration feed-forward, integration limits and dual biquad filters for sophisticated control of complex loads. A digital current loop utilising field oriented control gives users complete control over BLDC and DC brushed motors and seriously reduces noise in stepper motors.

The same card was used to meet the needs of the various transport systems throughout the machine, again enabling a high degree of flexibility in the design of different models of the unit. Further, the multi-motor support means that the designers could optimise motor selection in the system for both cost and performance.

For example, stepper motors were used in the two and three axis arms in the storage carousel, while brushless DC motors were fitted in the incubator. Motion functions for the handling of liquid and pump controls were incorporated in the design.

For the centrifuge, PMD recommended its ION digital drives – fully enclosed modules that provide high performance motion control, network connectivity and power amplification. PMD offers two output power choices, with the ION 500 rated at 500W and the ION 3000 rated at 3000W. Key features of the drives include their very high power density, ruggedness, and flexible form factor. They perform profile generation, servo compensation, stall detection, field oriented control, digital torque control and many other motion control functions.

In the centrifuge the ION digital drives operate in velocity profile mode with time break points. Using the velocity profile mode the centrifuge can be set up to run at various velocities at predetermined time points that match the specific process to achieve variable speed control and the resulting Relative Centrifugal Force (RCF). In this mode the motion is controlled by changing the acceleration, velocity, and deceleration parameters while the profile is being executed.

The ION supports up to two break-points, and the trigger condition can be one of up to ten parameters. For this application the trigger condition is time, and at each trigger point the acceleration and velocity parameters are updated, and the next set of parameters loaded.

Motion control programming for the Prodigy motion cards and ION digital drive was simplified through the use of PMD’s C-Motion development suite, which includes an extensive library of proven motion control code as well as an array of development and debug tools. The powerful C-Motion command set reduced the development time for the C/C+ programs running the on-board host.