Add youtube videos of the keynotes
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notes.org
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notes.org
@ -443,6 +443,9 @@ A nice way to have a 1dof flexure guiding with stiff frame is shown in Figure [[
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[[file:./figs/z_stage_triangles.png]]
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* Keynote: Mechatronic challenges in optical lithography :@hans_butler:
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yt:DF8GrWlMwEE
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** Introduction
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*Question*: in chip manufacturing, how do developments in optical lithography impact the mechatronic design?
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@ -605,6 +608,280 @@ The conclusions are:
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- EUV: all-vacuum stages
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- High-NA EUV: new optics, much larger accelerations
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* Keynote: High precision mechatronic approaches for advanced nanopositioning and nanomeasuring technologies :@eberhard_manske:
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yt:6hSWI1wtjfo
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** Coordinate Measurement Machines (CMM)
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Examples of Nano Coordinate Measuring Machines are shown in Figure [[fig:prec_cmm]].
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#+name: fig:prec_cmm
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#+caption: Example of Coordinate Measuring Machines
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#+attr_latex: :width \linewidth
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[[file:./figs/prec_cmm.png]]
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** Difference between CMM and nano-CMM
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With classical CMM, the Abbe-principle is not fulfilled in the x and y directions (Figure [[fig:prec_cmm_nano_cmm]]).
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The Abbe error can be determined with:
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\begin{equation}
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\Delta l_{x,y,z} = l_{x,y,z} \sin \Delta \phi_{x,y,z}
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\end{equation}
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Even with the best spindle: $l_{x,y} = 100 mm$ and $\Delta \phi = 2 \text{arcsec}$, we obtain an error of:
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\begin{equation}
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\Delta l = 0.1 \mu m
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\end{equation}
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which is not compatible with nano-meter precisions.
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Then, the classical CMM will not work for nano precision
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#+name: fig:prec_cmm_nano_cmm
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#+caption: Schematic of a CMM
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#+attr_latex: :scale 0.5
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[[file:./figs/prec_cmm_nano_cmm.png]]
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** How to do nano-CMM
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High precision mechatronic approaches are required for advanced nano-positionign and nano-measuring technologies:
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- High precision measurement concept
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- High precision measurement systems
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- High precision nano-sensors
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Combined with:
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- Advanced automatic control
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- Advanced measuring strategies
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** Concept - Minimization of the Abbe Error
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In order to minimize the Abbe error, the measuring "lines" should have a common point of intersection (Figure [[fig:prec_nano_cmm_concept]]).
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The 3D-realization of Abbe-principle is as follows:
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- 3 interferometers: cartesian coordinate system
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- probe located as the intersection point of the interferometers
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#+name: fig:prec_nano_cmm_concept
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#+caption: Error minimal measuring principle
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#+attr_latex: :scale 0.5
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[[file:./figs/prec_nano_cmm_concept.png]]
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** Minimization of residual Abbe error
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Still some residual Abbe error can happen as shown in Figure [[fig:prec_abbe_min]] due to both a change of angle and change of position.
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#+name: fig:prec_abbe_min
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#+caption: Residual Abbe error
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#+attr_latex: :width \linewidth
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[[file:./figs/prec_abbe_min.png]]
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** Compare of long travel guiding systems
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In order to have the Abbe error compatible with nano-meter precision, the precision of the spindle should be less and one arcsec which is not easily feasible with air bearing of precision roller bearing technologies as shown in Figure [[fig:prec_comp_guid]].
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#+name: fig:prec_comp_guid
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#+caption: Characteristics of guidings
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#+attr_latex: :scale 0.5
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[[file:./figs/prec_comp_guid.png]]
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** Extended 6 DoF Abbe comparator principle
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The solution used was to measure in real time the angles of the frame using autocollimators as shown in Figure [[fig:prec_6dof_abbe]] and then to minimize this tilt by close loop operation with additional actuators.
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The angular measurement error and control is less than $0.05 \text{arcses}$ which make the residual Abbe error:
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\begin{equation}
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\Delta l < 0.05\,nm
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\end{equation}
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Without an error-minimal approach, nano-meter precision cannot be achieved in large areas.
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#+name: fig:prec_6dof_abbe
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#+caption: Use of additional autocollimator and actuators for Abbe minimization
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#+attr_latex: :width \linewidth
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[[file:./figs/prec_6dof_abbe.png]]
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** Practical Realisation
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A practical realization of the Extended 6 DoF Abbe comparator principle is shown in Figure [[fig:prec_practical_6dof]].
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#+name: fig:prec_practical_6dof
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#+caption: Practical Realization of the
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#+attr_latex: :width \linewidth
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[[file:./figs/prec_practical_6dof.png]]
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** Tilt Compensation
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To measure compensate for any tilt, two solutions are proposed:
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1. Use a zero point angular auto-collimator (Figure [[fig:prec_tilt_corection]])
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- Resolution: 0.005 arcsec
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- Stability (1h): < 0.05 arcsec
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2. 6 DoF laser interferoemter (Figure [[fig:prec_tilt_corection_bis]])
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- Resolution: 0.00002 arcsec
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- Stability (1h): < 0.00005 arcsec
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#+name: fig:prec_tilt_corection
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#+caption: Auto-Collimator
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#+attr_latex: :scale 0.5
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[[file:./figs/prec_tilt_corection.png]]
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#+name: fig:prec_tilt_corection_bis
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#+caption: 6 Interferometers to measure tilts
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#+attr_latex: :scale 0.5
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[[file:./figs/prec_tilt_corection_bis.png]]
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** Comparison of long travail guiding systems - Bis
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Now, if we actively compensate the tilts are shown previously, we can fulfill the requirements as shown in Figure [[fig:prec_comp_guid_bis]].
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*Measurement and control technology to minimize Abbe errors to achieve*:
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- sub-nanometer precision
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- smaller moving mass
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- better dynamics
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#+name: fig:prec_comp_guid_bis
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#+caption: Characteristics of the tilt compensation system
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#+attr_latex: :width \linewidth
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[[file:./figs/prec_comp_guid_bis.png]]
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** Drive concept
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Usually, in order to achieve a large range over small resolution, each axis of motion is a combination of a coarse motion and a fine motion stage.
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The coarse motion stage generally consist of a stepper motor while the fine motion is a piezoelectric actuator.
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The approach here is to use an *homogenous drive concept for increase dynamics* (Figure [[fig:prec_drive_concept]]).
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Only one linear voice coil actuator is used which with large moving range and sub-nanometer resolution can be achieve at one time.
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#+name: fig:prec_drive_concept
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#+caption: Voice Coil Actuator
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#+attr_latex: :scale 0.5
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[[file:./figs/prec_drive_concept.png]]
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** NPMM-200 with extended measuring volume
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The NPMM-200 machine can be seen in Figure [[fig:prec_mechanics]].
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Characteristics:
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- Measuring range: 200 mm x 200 mm x 25 mm
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- Resolution: 20 pm
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- Abbe comparator principle
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- 6 laser interferometers
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- Active angular compensation
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- Position uncertainty < 4 nm
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- Measuring uncertainty up to 30 nm
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#+name: fig:prec_mechanics
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#+caption: Picture of the NPMM-200
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#+attr_latex: :width \linewidth
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[[file:./figs/prec_mechanics.png]]
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The NPMM-200 actually operates inside a Vacuum chamber as shown in Figure [[fig:prec_vacuum_cham]].
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#+name: fig:prec_vacuum_cham
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#+caption: Vacuum chamber used
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#+attr_latex: :scale 0.5
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[[file:./figs/prec_vacuum_cham.png]]
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** measurement capability
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Some step responses are shown in Figure [[fig:prec_results_meas]] and show the nano-metric precision of the machine.
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#+name: fig:prec_results_meas
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#+caption: Sub nano-meter position accuracy
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#+attr_latex: :width \linewidth
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[[file:./figs/prec_results_meas.png]]
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Picometer steps can even be achieved as shown in Figure [[fig:prec_results_pico]].
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#+name: fig:prec_results_pico
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#+caption: Picometer level control
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#+attr_latex: :width 0.6\linewidth
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[[file:./figs/prec_results_pico.png]]
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** Extension of the measuring range (700mm)
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If the measuring range is to be increase, there are some limits of the moving stage principle:
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- large moving masses (~300kg)
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- powerful drive systems required
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- nano-meter position capability problematic
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- large heat dissipation in the system
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- dynamics and dynamic deformation
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The proposed solution is to use *inverse dynamic concept for minimization of moving masses*.
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** Inverse kinematic concept - Tetrahedrical concept
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The proposed concept is shown in Figure [[fig:prec_inverse_kin]]:
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- mirrors and object to be measured are fixed
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- probe and interferometer heads are moved
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- laser beams virtually intersect in the probe tip
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- Tetrahedrical measuring volume
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This fulfills the Abbe principe but:
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- large construction space
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- difficult guide and drive concept
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#+name: fig:prec_inverse_kin
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#+caption: Tetrahedrical concept
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#+attr_latex: :scale 0.5
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[[file:./figs/prec_inverse_kin.png]]
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** Inverse kinematic concept - Scanning probe principle
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An other concept, the scanning probe principle is shown in Figure [[fig:prec_inverse_kin_scan]]:
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- cuboidal measuring volume
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- Fixed x-y-z mirrors
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- moving measuring head
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- guide and drive system outside measuring volume
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#+name: fig:prec_inverse_kin_scan
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#+caption: Scanning probe principle
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#+attr_latex: :scale 0.5
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[[file:./figs/prec_inverse_kin_scan.png]]
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** Inverse kinematic concept - Compact measuring head
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In order to minimize the moving mass, compact measuring heads have been developed.
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The goal was to make a lightweight measuring head (<1kg)
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The interferometer used are fiber coupled laser interferometers with a mass of 37g (Figure [[fig:prec_interferometers]]).
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#+name: fig:prec_interferometers
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#+caption: Micro Interferometers
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#+attr_latex: :scale 0.5
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[[file:./figs/prec_interferometers.png]]
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The concept is shown in Figure [[fig:prec_inverse_meas_head]]:
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- 6dof interferometers are used
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- one micro-probe
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- the total mass of the head is less than 1kg
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There is some abbe offset between measurement axis of probe and of interferometer but *Abbe error compensation by closed loop control of angular deviations* is used.
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#+name: fig:prec_inverse_meas_head
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#+caption:
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#+attr_latex: :scale 0.5
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[[file:./figs/prec_inverse_meas_head.png]]
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** Inverse kinematic concept - Scanning probe principle
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As shown in Figure [[fig:prec_abbe_compensation]], the abbe error can be compensated from the two top interferometers as:
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\[ \text{for } l_x = a: \quad \Delta l_{\text{Abbe}} = \Delta l_{\text{int}} \]
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Thus the tilt and Abbe errors can be compensated for with sub-nm resolution.
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#+name: fig:prec_abbe_compensation
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#+caption: Use of the interferometers to compensate for the Abbe errors
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#+attr_latex: :scale 0.5
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[[file:./figs/prec_abbe_compensation.png]]
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** Conclusion
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Proposed approaches to push the nano-positioning and nano-measuring technology:
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- Measurement and control technology to minimize Abbe errors
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- Homogeneous drive concept for increased dynamics
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- Inverse kinematic concept for minimization of moving mass
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- Abbe-error compensation by closed loop control of angular deviations
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* Designing anti-aliasing-filters for control loops of mechatronic systems regarding the rejection of aliased resonances :@ulrich_schonhoff:
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** The phenomenon of aliasing of resonances
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Weakly damped flexible modes of the mechanism can limit the performance of motion control systems.
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@ -1164,277 +1441,6 @@ The RR proposed algorithm is giving the best results
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- Computationally tractable design framework for large scale MIMO systems established
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- Near global optimal quality achieved on wafer stage setup using RR algorithm
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* Keynote: High precision mechatronic approaches for advanced nanopositioning and nanomeasuring technologies :@eberhard_manske:
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** Coordinate Measurement Machines (CMM)
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Examples of Nano Coordinate Measuring Machines are shown in Figure [[fig:prec_cmm]].
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#+name: fig:prec_cmm
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#+caption: Example of Coordinate Measuring Machines
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#+attr_latex: :width \linewidth
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[[file:./figs/prec_cmm.png]]
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** Difference between CMM and nano-CMM
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With classical CMM, the Abbe-principle is not fulfilled in the x and y directions (Figure [[fig:prec_cmm_nano_cmm]]).
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The Abbe error can be determined with:
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\begin{equation}
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\Delta l_{x,y,z} = l_{x,y,z} \sin \Delta \phi_{x,y,z}
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\end{equation}
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Even with the best spindle: $l_{x,y} = 100 mm$ and $\Delta \phi = 2 \text{arcsec}$, we obtain an error of:
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\begin{equation}
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\Delta l = 0.1 \mu m
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\end{equation}
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which is not compatible with nano-meter precisions.
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Then, the classical CMM will not work for nano precision
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#+name: fig:prec_cmm_nano_cmm
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#+caption: Schematic of a CMM
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#+attr_latex: :scale 0.5
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[[file:./figs/prec_cmm_nano_cmm.png]]
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** How to do nano-CMM
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High precision mechatronic approaches are required for advanced nano-positionign and nano-measuring technologies:
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- High precision measurement concept
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- High precision measurement systems
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||||
- High precision nano-sensors
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Combined with:
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- Advanced automatic control
|
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- Advanced measuring strategies
|
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** Concept - Minimization of the Abbe Error
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In order to minimize the Abbe error, the measuring "lines" should have a common point of intersection (Figure [[fig:prec_nano_cmm_concept]]).
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The 3D-realization of Abbe-principle is as follows:
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- 3 interferometers: cartesian coordinate system
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- probe located as the intersection point of the interferometers
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#+name: fig:prec_nano_cmm_concept
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#+caption: Error minimal measuring principle
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#+attr_latex: :scale 0.5
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[[file:./figs/prec_nano_cmm_concept.png]]
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** Minimization of residual Abbe error
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Still some residual Abbe error can happen as shown in Figure [[fig:prec_abbe_min]] due to both a change of angle and change of position.
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#+name: fig:prec_abbe_min
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#+caption: Residual Abbe error
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#+attr_latex: :width \linewidth
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[[file:./figs/prec_abbe_min.png]]
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** Compare of long travel guiding systems
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In order to have the Abbe error compatible with nano-meter precision, the precision of the spindle should be less and one arcsec which is not easily feasible with air bearing of precision roller bearing technologies as shown in Figure [[fig:prec_comp_guid]].
|
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#+name: fig:prec_comp_guid
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#+caption: Characteristics of guidings
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#+attr_latex: :scale 0.5
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[[file:./figs/prec_comp_guid.png]]
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** Extended 6 DoF Abbe comparator principle
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|
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The solution used was to measure in real time the angles of the frame using autocollimators as shown in Figure [[fig:prec_6dof_abbe]] and then to minimize this tilt by close loop operation with additional actuators.
|
||||
|
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The angular measurement error and control is less than $0.05 \text{arcses}$ which make the residual Abbe error:
|
||||
\begin{equation}
|
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\Delta l < 0.05\,nm
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\end{equation}
|
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|
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Without an error-minimal approach, nano-meter precision cannot be achieved in large areas.
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#+name: fig:prec_6dof_abbe
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#+caption: Use of additional autocollimator and actuators for Abbe minimization
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#+attr_latex: :width \linewidth
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[[file:./figs/prec_6dof_abbe.png]]
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** Practical Realisation
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A practical realization of the Extended 6 DoF Abbe comparator principle is shown in Figure [[fig:prec_practical_6dof]].
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#+name: fig:prec_practical_6dof
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#+caption: Practical Realization of the
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#+attr_latex: :width \linewidth
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[[file:./figs/prec_practical_6dof.png]]
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** Tilt Compensation
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To measure compensate for any tilt, two solutions are proposed:
|
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1. Use a zero point angular auto-collimator (Figure [[fig:prec_tilt_corection]])
|
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- Resolution: 0.005 arcsec
|
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- Stability (1h): < 0.05 arcsec
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2. 6 DoF laser interferoemter (Figure [[fig:prec_tilt_corection_bis]])
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- Resolution: 0.00002 arcsec
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- Stability (1h): < 0.00005 arcsec
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#+name: fig:prec_tilt_corection
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#+caption: Auto-Collimator
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#+attr_latex: :scale 0.5
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[[file:./figs/prec_tilt_corection.png]]
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#+name: fig:prec_tilt_corection_bis
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#+caption: 6 Interferometers to measure tilts
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#+attr_latex: :scale 0.5
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[[file:./figs/prec_tilt_corection_bis.png]]
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|
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** Comparison of long travail guiding systems - Bis
|
||||
|
||||
Now, if we actively compensate the tilts are shown previously, we can fulfill the requirements as shown in Figure [[fig:prec_comp_guid_bis]].
|
||||
|
||||
*Measurement and control technology to minimize Abbe errors to achieve*:
|
||||
- sub-nanometer precision
|
||||
- smaller moving mass
|
||||
- better dynamics
|
||||
|
||||
#+name: fig:prec_comp_guid_bis
|
||||
#+caption: Characteristics of the tilt compensation system
|
||||
#+attr_latex: :width \linewidth
|
||||
[[file:./figs/prec_comp_guid_bis.png]]
|
||||
|
||||
** Drive concept
|
||||
|
||||
Usually, in order to achieve a large range over small resolution, each axis of motion is a combination of a coarse motion and a fine motion stage.
|
||||
The coarse motion stage generally consist of a stepper motor while the fine motion is a piezoelectric actuator.
|
||||
|
||||
The approach here is to use an *homogenous drive concept for increase dynamics* (Figure [[fig:prec_drive_concept]]).
|
||||
|
||||
Only one linear voice coil actuator is used which with large moving range and sub-nanometer resolution can be achieve at one time.
|
||||
|
||||
#+name: fig:prec_drive_concept
|
||||
#+caption: Voice Coil Actuator
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#+attr_latex: :scale 0.5
|
||||
[[file:./figs/prec_drive_concept.png]]
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|
||||
** NPMM-200 with extended measuring volume
|
||||
|
||||
The NPMM-200 machine can be seen in Figure [[fig:prec_mechanics]].
|
||||
|
||||
Characteristics:
|
||||
- Measuring range: 200 mm x 200 mm x 25 mm
|
||||
- Resolution: 20 pm
|
||||
- Abbe comparator principle
|
||||
- 6 laser interferometers
|
||||
- Active angular compensation
|
||||
- Position uncertainty < 4 nm
|
||||
- Measuring uncertainty up to 30 nm
|
||||
|
||||
#+name: fig:prec_mechanics
|
||||
#+caption: Picture of the NPMM-200
|
||||
#+attr_latex: :width \linewidth
|
||||
[[file:./figs/prec_mechanics.png]]
|
||||
|
||||
The NPMM-200 actually operates inside a Vacuum chamber as shown in Figure [[fig:prec_vacuum_cham]].
|
||||
|
||||
#+name: fig:prec_vacuum_cham
|
||||
#+caption: Vacuum chamber used
|
||||
#+attr_latex: :scale 0.5
|
||||
[[file:./figs/prec_vacuum_cham.png]]
|
||||
|
||||
** measurement capability
|
||||
|
||||
Some step responses are shown in Figure [[fig:prec_results_meas]] and show the nano-metric precision of the machine.
|
||||
|
||||
#+name: fig:prec_results_meas
|
||||
#+caption: Sub nano-meter position accuracy
|
||||
#+attr_latex: :width \linewidth
|
||||
[[file:./figs/prec_results_meas.png]]
|
||||
|
||||
Picometer steps can even be achieved as shown in Figure [[fig:prec_results_pico]].
|
||||
|
||||
#+name: fig:prec_results_pico
|
||||
#+caption: Picometer level control
|
||||
#+attr_latex: :width 0.6\linewidth
|
||||
[[file:./figs/prec_results_pico.png]]
|
||||
|
||||
** Extension of the measuring range (700mm)
|
||||
|
||||
If the measuring range is to be increase, there are some limits of the moving stage principle:
|
||||
- large moving masses (~300kg)
|
||||
- powerful drive systems required
|
||||
- nano-meter position capability problematic
|
||||
- large heat dissipation in the system
|
||||
- dynamics and dynamic deformation
|
||||
|
||||
The proposed solution is to use *inverse dynamic concept for minimization of moving masses*.
|
||||
|
||||
** Inverse kinematic concept - Tetrahedrical concept
|
||||
|
||||
The proposed concept is shown in Figure [[fig:prec_inverse_kin]]:
|
||||
- mirrors and object to be measured are fixed
|
||||
- probe and interferometer heads are moved
|
||||
- laser beams virtually intersect in the probe tip
|
||||
- Tetrahedrical measuring volume
|
||||
|
||||
This fulfills the Abbe principe but:
|
||||
- large construction space
|
||||
- difficult guide and drive concept
|
||||
|
||||
#+name: fig:prec_inverse_kin
|
||||
#+caption: Tetrahedrical concept
|
||||
#+attr_latex: :scale 0.5
|
||||
[[file:./figs/prec_inverse_kin.png]]
|
||||
|
||||
** Inverse kinematic concept - Scanning probe principle
|
||||
|
||||
An other concept, the scanning probe principle is shown in Figure [[fig:prec_inverse_kin_scan]]:
|
||||
- cuboidal measuring volume
|
||||
- Fixed x-y-z mirrors
|
||||
- moving measuring head
|
||||
- guide and drive system outside measuring volume
|
||||
|
||||
#+name: fig:prec_inverse_kin_scan
|
||||
#+caption: Scanning probe principle
|
||||
#+attr_latex: :scale 0.5
|
||||
[[file:./figs/prec_inverse_kin_scan.png]]
|
||||
|
||||
** Inverse kinematic concept - Compact measuring head
|
||||
|
||||
In order to minimize the moving mass, compact measuring heads have been developed.
|
||||
The goal was to make a lightweight measuring head (<1kg)
|
||||
|
||||
The interferometer used are fiber coupled laser interferometers with a mass of 37g (Figure [[fig:prec_interferometers]]).
|
||||
|
||||
#+name: fig:prec_interferometers
|
||||
#+caption: Micro Interferometers
|
||||
#+attr_latex: :scale 0.5
|
||||
[[file:./figs/prec_interferometers.png]]
|
||||
|
||||
The concept is shown in Figure [[fig:prec_inverse_meas_head]]:
|
||||
- 6dof interferometers are used
|
||||
- one micro-probe
|
||||
- the total mass of the head is less than 1kg
|
||||
|
||||
There is some abbe offset between measurement axis of probe and of interferometer but *Abbe error compensation by closed loop control of angular deviations* is used.
|
||||
|
||||
#+name: fig:prec_inverse_meas_head
|
||||
#+caption:
|
||||
#+attr_latex: :scale 0.5
|
||||
[[file:./figs/prec_inverse_meas_head.png]]
|
||||
|
||||
** Inverse kinematic concept - Scanning probe principle
|
||||
|
||||
As shown in Figure [[fig:prec_abbe_compensation]], the abbe error can be compensated from the two top interferometers as:
|
||||
\[ \text{for } l_x = a: \quad \Delta l_{\text{Abbe}} = \Delta l_{\text{int}} \]
|
||||
Thus the tilt and Abbe errors can be compensated for with sub-nm resolution.
|
||||
|
||||
#+name: fig:prec_abbe_compensation
|
||||
#+caption: Use of the interferometers to compensate for the Abbe errors
|
||||
#+attr_latex: :scale 0.5
|
||||
[[file:./figs/prec_abbe_compensation.png]]
|
||||
|
||||
** Conclusion
|
||||
|
||||
Proposed approaches to push the nano-positioning and nano-measuring technology:
|
||||
- Measurement and control technology to minimize Abbe errors
|
||||
- Homogeneous drive concept for increased dynamics
|
||||
- Inverse kinematic concept for minimization of moving mass
|
||||
- Abbe-error compensation by closed loop control of angular deviations
|
||||
|
||||
* Reducing control delay times to enhance dynamic stiffness of magnetic bearings :@jan_philipp_schmidtmann:
|
||||
** Introduction
|
||||
This projects focuses on reducing the control delay times of a magnetic bearing shown in Figure [[fig:magn_bear_intro]].
|
||||
|
||||
Loading…
Reference in New Issue
Block a user