A system for a projection exposure apparatus which comprises a first component, a second component, and a decoupling device configured to decouple the second component in more than one degree of freedom from mechanical excitations of the first component. The decoupling device comprises first decoupling elements which have a positive stiffness. The decoupling device also comprises second decoupling elements, which have a negative stiffness. The decoupling device further comprises a third component, which is arranged between the first and second components.

A vibration isolator with a pneumatic spring that is effective only in vertical direction, the pneumatic spring including a working space in which a vertically effective actuator is disposed.

The invention relates a method for manufacturing a damper device including a first part and a second part, said method comprising the following steps: a) providing a damping material in a space in between the first part and the second part, such that the damping material is in a compressed state in the space; and b) heating the device to a predetermined temperature in order to adhere the damping material to the first part and the second part.

The invention provides a pneumatic support device for a lithographic apparatus and a lithographic apparatus with such support device. The support device comprises a gas spring. The gas spring comprises a suspending part, a suspended part, and a pressure chamber configured for supporting the suspended part relative to the suspending part. The support device further comprises an actuator configured for positioning the suspended part relative to the suspending part, an acceleration sensor configured for generating a first sensor signal representative for the acceleration of the suspending part, a pressure sensor configured for generating a second sensor signal representative for the pressure in the pressure chamber, and a control unit. The control unit is configured to: receive the first sensor signal, receive the second sensor signal, filter the first sensor signal in a low-pass filter, filter the second sensor signal in a high-pass filter, determine, based on the filtered first sensor signal and filtered second sensor signal, a force exerted by the suspending part on the suspended part, and generate, based on said force, a control signal for the actuator.

The present invention relates to a lithographic apparatus, comprising: a projection system configured to project a patterned radiation beam onto a substrate, comprising optical elements, a sensor frame, a first position measurement system configured to measure a position of an optical element relative to the sensor frame, comprising a sensor adapted to monitor an optical element, with a sensor element mounted to the sensor frame, a sensor frame support supporting the sensor frame on a reference, a force measurement device adapted to generate force measurement data relating to force exerted on the sensor frame by the sensor frame support, a position control device adapted to control the relative position of the substrate and the patterned radiation beam wherein the position control device is configured to receive the force measurement data and to control said relative position based on at least the force measurement data.

The invention provides a vibration isolation system (IS), comprising a piston (402) to carry a payload, a connecting member (410), a spring (404) and a flexible member (408). The spring is arranged to support the piston along a direction with a positive stiffness. The flexible member is arranged to apply a force to the piston along the direction via the connecting member with a negative stiffness.

The invention relates to support structure, comprising: a first body; a second body; a first support having a first stiffness; a second support having a second stiffness, wherein the second body supports the first body at a first location via the first support, wherein the second body supports the first body at a second location via the second support; a position measurement system arranged to generate a deformation signal representative of a difference of deformation of the first body and the second body relative to each other; a first actuator to apply a force between the first body and the second body at or near the first location; a second actuator to apply a force between the first body and the second and body at or near the second location; wherein the support structure comprises a controller arranged to determine a deformation compensation signal on the basis of the first stiffness, the second stiffness and the deformation signal and to drive at least one of the first actuator and the second actuator on the basis of the deformation compensation signal to prevent or at least reduce deformation of the first body.

The present invention relates to a positioning system, including: a first actuator to exert an actuation force on a moveable body, the first actuator being coupled to a balance mass configured to absorb a reaction force resulting from the actuation force, the actuation force providing an acceleration of the moveable body and the reaction force providing an acceleration of the balance mass, wherein a force resulting from the acceleration of the moveable body together with a force resulting from the acceleration of the balance mass result in a balance mass torque; a balance mass support to support the balance mass onto a frame, which balance mass support engages the frame at a support position; and a torque compensator; wherein the torque compensator exerts a compensation force to compensate the balance mass torque, and wherein the torque compensator exerts the compensation force on the frame at the support position.

An imprint lithography apparatus having a first frame to be mounted on a floor, a second frame mounted on the first frame via a kinematic coupling, an alignment sensor mounted on the second frame, to align an imprint lithography template arrangement with a target portion of a substrate, and a position sensor to measure a position of the imprint lithography template arrangement and/or a substrate stage relative to the second frame.

The disclosure relates to an optical module with first and second components, a supporting structure and an anticollision device. The first component is supported by the supporting structure and is arranged adjacent to and at a distance from the second component to form a gap. The supporting structure defines a path of relative movement, on which the first and second components move in relation to one another under the influence of a disturbance, a collision between collision regions of the first and second components occurring if the anticollision device is inactive. The anticollision device includes a first anticollision unit on the first component, which produces a first field, and a second anticollision unit on the second component, which is assigned to the first anticollision unit and produces a second field.