A nanoscale positioning apparatus with a large stroke and multiple degrees of freedom and a control method thereof are provided. The nanoscale positioning apparatus includes a base, a plurality of parallel branch chain mechanisms and a working table. Each of the parallel branch chain mechanisms includes an electric cylinder, a micro-motion drive mechanism, a laser interferometer, a grating measuring device, a self-locking upper hinge and a self-locking lower hinge. The top of the base is connected to one end of the electric cylinder through the self-locking lower hinge. The other end of the electric cylinder is connected to one end of the micro-motion drive mechanism. The other end of the micro-motion drive mechanism is connected to the bottom of the working table through the self-locking upper hinge. The positioning apparatus has multiple degrees of freedom, and realizes multi-degree-of-freedom arbitrary position adjustment of the working table through parallel branch chain mechanisms.

An apparatus and system for determining alignment of a substrate in which a periodic alignment mark is illuminated with spatially coherent radiation which is then provided to a compact integrated optical device to create self images of the alignment mark which may be manipulated (e.g., mirrored, polarized) and combined to obtain information on the position of the mark and distortions within the mark. Also disclosed is a system for determining alignment of a substrate in which a periodic alignment mark is illuminated with spatially coherent radiation which is then provided to an optical fiber arrangement to obtain information such as the position of the mark and distortions within the mark.

Disclosed is a method of determining calibrated reference exposure and measure grids for referencing position of a substrate stage in a lithographic system. The method comprises obtaining calibration data relating to one or more calibration substrates; and determining an exposure grid for an exposure side of the lithographic system from said calibration data and a measure grid for a measure side of the lithographic system from said calibration data. The exposure grid and said measure grid are decomposed so as to remove a calibration substrate dependent component from said exposure grid and from said measure grid to obtain a substrate independent exposure grid and substrate independent measure grid.

A liquid crystal exposure apparatus that moves a substrate supported in a noncontact manner by a noncontact holder to a projection optical system, and performs scanning exposure to the substrate equipped with: holding pads that hold a part of the substrate located at a first position above the noncontact holder; adsorption pads that hold another part of the substrate; a first drive section moves the holding pads from below the substrate direction intersecting a vertical direction, where the substrate is located at the first position held by the adsorption pads; and a second drive section that moves the adsorption pads holding the substrate, to a second position where the substrate is supported in a noncontact manner by the noncontact holder, wherein the scanning exposure, the second drive section moves the adsorption pads holding the substrate supported in a noncontact manner by the noncontact holder to the projection optical system.

A method of unloading an object from a support table, the object clamped to the support table during an exposure process by: applying a first pressure to a central region of the support table under a central portion of the object; and applying a second pressure to a peripheral region of the support table under a peripheral portion of the object, wherein during clamping the first pressure and the second pressure are controlled such that liquid is retained between the object and a seal member that is positioned radially between the central region and the peripheral region at an upper surface of the support table and protrudes towards the object, the method including: increasing the first pressure towards ambient pressure; removing at least some of the liquid retained between the object and the seal member by decreasing the second pressure; and increasing the second pressure towards the ambient pressure.

A measurement apparatus for measuring a height position of an object is provided. The apparatus comprises a light projector that projects measurement light onto the object, a light receiver that receives the measurement light reflected by the object, and a processor that determines a height position of the object based on an image of the measurement light received by the light receiver. The light projector projects a coarse detection pattern and a fine detection pattern having a periodic pattern onto the object, and the processor determines a coarse detection value of a height position of the object based on the coarse detection pattern received by the light receiver, and determines a fine detection value of a height position of the object based on the coarse detection value and the fine detection pattern received by the light receiver.

A method for calibrating a mirror of an interferometer system configured to measure a position of an object using two interferometers of the interferometer system that are arranged at opposite sides of the object and configured to measure the position of the object in the same X-direction, wherein two sets of measurements are obtained for different rotational orientations about an axis perpendicular to the X-direction to determine a shape of the mirror. There is also provided a position measuring method in which the obtained shape of the mirror is used to adjust measurements in the X-direction, a lithographic apparatus and a device manufacturing method making use of such a lithographic apparatus.

A self-calibrating overlay metrology system may receive device overlay data from device targets on a sample, determine preliminary device overlay measurements for the device targets including device-scale features using an overlay recipe with the device overlay data as inputs, receive assist overlay data from sets of assist targets on the sample including device-scale features, where a particular set of assist targets includes one or more target pairs formed with two overlay targets having programmed overlay offsets of a selected value with opposite signs along a particular measurement direction. The system may further determine self-calibrating assist overlay measurements for the sets of assist targets based on the assist overlay data, where the self-calibrating assist overlay measurements are linearly proportional to overlay on the sample, and generate corrected overlay measurements for the device targets by adjusting the preliminary device overlay measurements based on the self-calibrating assist overlay measurements.

In a beam irradiation apparatus in which a movable body holds an object, a mark detection system detects a first mark on the movable body while moving the movable body in a first direction and changing an irradiation position of a measurement beam in the first direction, the mark detection system detects a second mark while moving the movable body in the first direction and changing the irradiation position of the measurement beam in the first direction, a controller controls a position of the movable body in a second direction intersecting the first direction during a time period between the detection of the first mark and the detection of the second mark, and the controller controls the movement of the movable body to adjust a positional relation between the object on the movable body and a processing beam, based on results of the detection of the first and second marks.

A broadband light source includes a rotatable drum coated with plasma-forming target material, a rotational actuator configured to rotate the rotatable drum, and a rotary encoder connected to the rotatable drum. The broadband light source may include a linear actuator configured to axially translate the rotatable drum and linear encoder connected to the rotatable drum. The broadband light source includes a pulsed laser source configured to direct pulsed illumination to a set of spots on the material-coated portion of the rotatable drum for exciting the plasma-forming target material and emitting broadband light as the drum is actuated. The broadband light source includes a control system. The control system is configured to receive one or more rotational position indicators from the rotary indicator and control triggering of the laser source based on the one or more rotational position indicators from rotary encoder.