Abstract: A stand for a surgical microscope includes a first stand part including a first bearing and a second bearing, a shaft arranged in the first bearing and defining a rotation axis, a second stand part fixedly connected to the shaft, mounted on the first stand part together with the shaft pivotably about the rotation axis, and including a force transmission point, a lever part mounted on the second stand part at the force transmission point, arranged pivotably about the rotation axis, and including a third bearing, and a torque compensation assembly applying a counter torque to the second stand part to compensate a load torque including a dynamic load torque occurring when the second stand part is pivoted about the rotation axis and a static load torque resulting from a gravitation force acting on the second stand part and on elements mounted on the second stand part.

Abstract: A method for operating a surgical microscope having a camera is described. The method includes the following steps: a code that is able to be captured in a set frequency range is introduced into the field of view of the camera, at least one image which includes the code is captured via the camera, an evaluation device is used to identify the code and compare the latter to set features of a code required to activate at least one function, and if the identified code has the set features, the activation of the function is authorized.

Abstract: A stand for a surgical microscope includes a first stand part including a first bearing and a second bearing, a shaft arranged in the first bearing and defining a rotation axis, a second stand part fixedly connected to the shaft, mounted on the first stand part together with the shaft pivotably about the rotation axis, and including a force transmission point, a lever part mounted on the second stand part at the force transmission point, arranged pivotably about the rotation axis, and including a third bearing, and a torque compensation assembly applying a counter torque to the second stand part to compensate a load torque including a dynamic load torque occurring when the second stand part is pivoted about the rotation axis and a static load torque resulting from a gravitation force acting on the second stand part and on elements mounted on the second stand part.

Abstract: The disclosure relates to a device for transmitting electrical signals between a first interface element, arranged at a first structure of a lithography system, and a second interface element, arranged at a second structure of the lithography system. An electrical conductor connects the first interface element and the second interface element. The device has a hollow body which surrounds at least sections of the electrical conductor and which is designed to electromagnetically shield the electrical conductor. A gap is provided in the hollow body or between the hollow body and one of the structures and allows a relative movement of the first structure and the second structure to mechanically decouple the first structure from the second structure.

Abstract: The disclosure relates to a device for transmitting electrical signals between a first interface element, arranged at a first structure of a lithography system, and a second interface element, arranged at a second structure of the lithography system. An electrical conductor connects the first interface element and the second interface element. The device has a hollow body which surrounds at least sections of the electrical conductor and which is designed to electromagnetically shield the electrical conductor. A gap is provided in the hollow body or between the hollow body and one of the structures and allows a relative movement of the first structure and the second structure to mechanically decouple the first structure from the second structure.

Abstract: In a position measuring device (5) and a method for ascertaining positions of an object (3) to be measured, at least one capacitive position measuring sensor (7) provides a position measurement signal (PM) relating to the object (3) to be measured and at least one capacitive reference measurement sensor (14) provides a reference measurement signal (RM). The measuring sensors (7, 14) are connected to a computing unit (8) which is embodied to calculate a position signal (P) to ascertain the positions from the position measurement signal (PM) and the reference measurement signal (RM). As a result of interfering influences being contained substantially equally in the position measurement signal (PM) and the reference measurement signal (RM) as an interference signal (S), it is possible to determine and eliminate the interference signal (S) during the calculation.

Abstract: In a position measuring device (5) and a method for ascertaining positions of an object (3) to be measured, at least one capacitive position measuring sensor (7) provides a position measurement signal (PM) relating to the object (3) to be measured and at least one capacitive reference measurement sensor (14) provides a reference measurement signal (RM). The measuring sensors (7, 14) are connected to a computing unit (8) which is embodied to calculate a position signal (P) to ascertain the positions from the position measurement signal (PM) and the reference measurement signal (RM). As a result of interfering influences being contained substantially equally in the position measurement signal (PM) and the reference measurement signal (RM) as an interference signal (S), it is possible to determine and eliminate the interference signal (S) during the calculation.