Abstract: A lithographic apparatus is disclosed that includes an encoder type sensor system configured to measure a position of a substrate table of the lithographic apparatus relative to a reference structure. The encoder type sensor system includes an encoder sensor head and an encoder sensor target and the lithographic apparatus comprises a recess to accommodate the encoder sensor target.

Abstract: A displacement measurement system, in particular for measuring the displacement of a substrate table in a lithographic apparatus relative to a reference frame is presented. The displacement measure system includes a plurality of displacement sensors mounted to the substrate table and a target associated with each displacement sensor mounted to the reference frame.

Abstract: A lithographic apparatus includes a displacement measuring system to measure a position of a moveable object with respect to a reference frame of the lithographic apparatus, in at least three coplanar degrees of freedom (x, y, Rz) of an orthogonal x-y-z coordinate system centred in the center of the moveable object. The moveable object includes a support structure configured to support a patterning device or a substrate table configured to support a substrate. The displacement measuring system includes at least three sensor heads, each sensor head being positioned with a measuring direction substantially coplanar with the x-y plane of the coordinate system and each sensor head being furthermore positioned with the measuring direction substantially perpendicular to a connection line connecting the sensor head with the center of the movable object and extending coplanar with the x-y plane.

Abstract: A device manufacturing method includes projecting a patterned beam of radiation onto a substrate, wherein the position of a movable object is determined in a number of degrees of freedom using a number of sensors, the number of sensors being larger than the number of degrees of freedom, wherein the position of the movable object in the number of degrees of freedom is determined using signals of each of the sensors, wherein the signals of the sensors are weighed on the basis of the difference between noise levels of each of the sensors. Accuracy of the position measurement of movable object and/or overlay and focus performance are improved in lithographic apparatus.

Abstract: A measurement unit to determine a position in a first and second dimension includes a diffraction type encoder and an interferometer. The diffraction type encoder determines by means of a diffraction on a first and a second diffraction grating the position in the first dimension of the second grating with respect to the first grating, The interferometer determines the position in the second dimension of a mirror. The measurement unit includes a combined optical unit to transfer an encoder measurement beam as well as an interferometer measurement beam. Further, the measurement unit may include a combined light source for the encoder as well as the interferometer. One of the first and second diffraction gratings may further show some degree of zero order reflection to provide the mirror of the interferometer.

Abstract: A position measurement system for measuring a position of an object is described, the system including: a first incremental measurement unit for measuring a first number of first distance steps in a distance between a reference frame and the object, wherein the first number equals a first integer value plus a first fraction, and a second incremental measurement unit for measuring a second number of second distance steps in a distance between the reference frame and the object, wherein the second number equals a second integer value plus a second fraction, wherein the position measurement system is constructed and arranged to initialize the second incremental measurement unit on the basis of the first number and the second fraction.

Abstract: A lithographic apparatus comprises an illumination system, an array of individually controllable elements, a substrate table, a projection system, a position encoder, an imaging device, and an image processing unit. The illumination system conditions a radiation beam. The array of individually controllable elements modulates the cross-section of the radiation beam. The substrate table supports a substrate. The projection system projects the modulated radiation beam onto a target portion of the substrate, thereby applying a pattern to the target portion of the substrate. The pattern comprises a first line and a second line. The first line is offset from the second line. The position encoder determines a position of the substrate table. The position encoder comprises a position sensor and a scale. The scale comprises a plurality of lines intended to be straight and parallel to one another. The imaging device obtains an image of the first line and the second line.

Abstract: A lithographic apparatus includes a displacement measuring system configured to measure the position of a substrate table in at least three degrees of freedom. The displacement measuring system includes a first x-sensor configured to measure the position of the substrate table in a first direction and a first and a second y-sensor configured to measure the position of the substrate table in a second direction. Said displacement measuring system further comprises a second x-sensor. The first and second x-sensor and first and second y-sensors are encoder type sensors configured to measure the position of each of the sensors with respect to at least one grid plate. The displacement measuring system is configured to selectively use, depending on the position of the substrate table, three of the first and second x-sensors and the first and second y-sensors to determine the position of the substrate table in three degrees of freedom.

Abstract: A lithographic apparatus includes a radiation source configured to provide radiation to an illumination system, the radiation source configured to provide radiation in a first wavelength range and in a second wavelength range, the second wavelength range being different from the first wavelength range. A support is configured to support a patterning device, the patterning device is configured to impart the radiation with a pattern in its cross-section. A substrate table is configured to hold a substrate, and a projection system is configured to project the patterned radiation onto a target portion of a substrate. The first wavelength range is the primary wavelength of the lithographic apparatus. The second wavelength range is used for setup of the lithographic apparatus, the setup including one or more of calibration, qualification, performance test, and alignment. The second wavelength range may also be used for exposure of a further substrate.

Abstract: The invention pertains to a lithographic apparatus including a radiation system configured to condition a beam of radiation; a projection system configured to project the beam of radiation onto a target portion of a substrate; a displacement device configured to move the moveable object relative to the projection system in substantially a first direction and a second direction differing from the first direction; and a measuring device configured to measure a displacement of the moveable object in a third direction, which is substantially perpendicular to the first direction and to the second direction, wherein the measuring device may include an encoder system.