Nanopositioning Systems and Advanced Motion Control for DNA Sequencing

Depending on the design, images can be captured while the sample is in motion or in a static position, after a step and settle process. With step and settle, the exact location is known when the controller provides the information that the desired position has been reached.  With the continuous motion method, the relevant position can either be calculated based on time, which means the following error and velocity constancy of a motion system are very critical, or by setting up triggers that are based on encoder signals and thus real-time position of the motion stage. In both cases, the stage accuracy, i.e., the deviation from the assumed position including encoder errors, servo bandwidth limitations and geometric errors have an influence on the quality of the imaging process.

Advanced system architecture and control algorithms, such as those on the ACS controller platform employed by PI motion systems, allow extremely tight velocity regulation and very fast step and settle times. Access to encoder signals is also made available with microsecond level precision. Using real-time encoder signals is the better method – it allows triggering of the camera at the right time, in the right position and improves the imaging quality.   

On the stage side, the best performance in velocity control is enabled by using ironless, non-cogging linear motors — such as integrated in PI’s compact V-508 nanopositioning stage family or A-143 air bearing stage — or voice coil motors — such as used in the V-308 vertical nano-focusing stage. When maximum force in a compact package is required, iron-core motors are available. The undesired cogging behavior of iron-core motors can be significantly reduced with the anti-cogging control algorithms available on PI’s ACS-based motion controllers, resulting in a drastic improvement in velocity constancy.

For XY stage applications, geometric accuracy is very critical for system performance. Straightness, flatness, pitch, yaw, and roll errors contribute to the overall position uncertainty or sphere of confusion.  Flatness deviations lead to vertical position fluctuations that need to be compensated by the vertical focusing mechanism. So, there is a commercial trade-off between dynamic requirements of the Z-focusing stage and the vertical ripple of the XY stage. Typically, 100nm flatness and straightness per millimeter of horizontal motion should not be exceeded. The higher the horizontal desired speed, the higher the Z-focusing stage dynamics requirements to deal with the higher frequency of the vertical fluctuations. If the Z-focusing stage is the limiting factor, a better XY-stage design with improved flatness is needed. The highest Z-focusing performance is typically available from piezo-flexure drives, such as PI’s P-725 PIFOC nano-focusing stages as these provide travel ranges up to 800µm. When even longer Z-travel ranges are needed, the V-308 voice-coil focus stage provides 7mm, a great alternative, also with nanoscale precision. Here, the PIone ultra-high precision encoder with 2µm pitch and 1nm resolution is employed. Gravity forces to 1kg can be compensated by the integrated, adjustable magnetic counterbalance. The counterbalance improves the motor performance by keeping it cooler, not having to work against gravity all the time. The net result is a cooler-running, higher dynamic system with a nice safety feature as a side-effect: in a power loss situation, the expensive optics on the stage will not crash into the sample.

Step and settle motion is generally a slower process than continuous scanning, similar to stop and go traffic vs. free flowing traffic. This process involves acceleration, deceleration, and waiting until a stable position has been reached before an image can be captured. The higher the mechanical resonant frequency (equivalent to the stiffness of the system), the shorter the settling time. To ensure excellent in-position stability, optics-based systems often utilize a stepper motor / lead screw combination as the driving mechanism. If the stepper motor is dimensioned correctly, it can be operated in open-loop, preventing servo jitter issues that may arise in closed-loop systems. However, to verify position accuracy, a linear encoder can also be added. The combination of stepper motor and fine pitch lead screw is obviously slower than a continuous-scan, linear motor-based approach. However, this may not matter, if the majority of the cycle time is dictated by other processes.

If the motion system is the limiting factor, an ironless linear motor stage is the logical consequence. The linear motor solution allows for significantly higher acceleration and speeds of 1000mm/sec and more are feasible. Modern encoders provide resolutions below 1 nanometer, essential to achieve the required level of stability. Besides the higher motion performance of the linear motor, the absence of friction and wear as opposed to leadscrew-drives is a significant plus, also when it comes to maintenance and lifetime.

Precision motion control and automation play pivotal roles in democratizing DNA sequencing by driving down the costs. When looking for the right partner, assess the experience and expertise of each vendor. PI has a proven track record of delivering high-quality standard and custom motion systems for genome sequencing applications. Supported by the largest portfolio of precision motion technologies, customers have the choice of piezoelectric, voice-coil, and 3-phase motor drive systems and can select from a variety of guiding systems including flexures, cross-roller bearings, air bearings, and magnetic-bearings. Drawing from five+ decades of nanopositioning experience with customers in the most demanding industries, including semiconductor and super-resolution microscopy manufacturers, we have honed our expertise to deliver cutting-edge solutions that meet the highest standards of precision, reliability, and performance.

If you would like more information about our full product range for genome sequencing, simply contact a member of the PI team directly.