Abstract: The present invention relates to a method for determining the spatial position of objects, in particular objects, comprising the steps of: —acquiring first position data which comprise first position information describing the spatial position of an object (2) within a first co-ordinate system (A); —acquiring first transformation data which comprise first transformation information describing a transformation of the object's position from the first co-ordinate system (A) into a second co-ordinate system (B); —acquiring, on the basis of the first position data and the first transformation data, second position data which comprise second position information describing the spatial position of the object (2) within the second co-ordinate system (B); —acquiring second transformation data which comprise second transformation information describing a transformation of the object's position from the second co-ordinate system (B) into an inertial co-ordinate system (I); —determining, on the basis of the second positi

Abstract: The invention relates to a medical registration apparatus (1), comprising •two flanks (2a, 2b); •a pivot portion (3) around which at least one of the flanks (2a, 2b) is rotatable with respect to a rotation centre (3c, 3d) (FIG. 1, FIG. 3); •a contacting portion (4a, 4b) on each of the flanks (2a, 2b), each contacting portion (4a, 4b) being spaced apart from the rotation centre (3c, 3d); and •a sensor (5, 6) being arranged with an offset (r, FIG. 4 A) to a line (a) connecting the contacting portions (4a, 4b). The invention also relates to a data processing method for use with the medical registration apparatus.

Abstract: A method, performed by a computer, for measuring geometric length and offset differences of a subject element using landmarks obtained through, for example, analysis of medical data images. The method may include obtaining medical image data from a medical imaging device. The method includes measuring, by the computer, a first landmark vector between a femoral landmark and a second landmark at a first point in time from, for example, the medical data images. Further, the method includes measuring, by the computer, a second landmark vector between the femoral landmark and the second landmark at a second point in time which is later than the first point in time from, for example, the medical data images. Calculating an orthogonal projection of the first landmark vector into a sagittal plane and using the direction of the orthogonal projection of the first landmark vector into the sagittal plane as a length direction.

Abstract: A method, performed by a computer, for measuring geometric length and offset differences of a subject element using landmarks obtained through, for example, analysis of medical data images. The method may include obtaining medical image data from a medical imaging device. The method includes measuring, by the computer, a first landmark vector between a femoral landmark and a second landmark at a first point in time from, for example, the medical data images. Further, the method includes measuring, by the computer, a second landmark vector between the femoral landmark and the second landmark at a second point in time which is later than the first point in time from, for example, the medical data images. Calculating an orthogonal projection of the first landmark vector into a sagittal plane and using the direction of the orthogonal projection of the first landmark vector into the sagittal plane as a length direction.

Abstract: A data processing method for determining the relative orientation of an object coordinate system of an anatomical object in a global co-ordinate system, comprising the steps of: acquiring a reference direction dataset representing a first reference direction of a line between a first anatomical landmark of a reference object and a second anatomical landmark of the reference object, and a second reference direction of a line between a third anatomical landmark of the reference object and a fourth anatomical landmark of the reference object, wherein the first and second reference directions are given in a reference coordinate system and the reference object corresponds to the anatomical object; acquiring an object direction dataset representing a first object direction of a line between the first anatomical landmark of the anatomical object and the second anatomical landmark of the anatomical object, and a second object direction of a line between the third anatomical landmark of the anatomical object and the f

Abstract: The present invention relates to a method for determining the spatial position of objects, in particular medical objects. First position data is acquired that describes a spatial position of an object in a first coordinate system. First transformation data is acquired that transforms the object's position from the first coordinate system to a second coordinate system. Based on the foregoing data, second position data is acquired that specifies the spatial position of the object in the second coordinate system. Second transformation data is acquired that transforms the object's position from the second coordinate system to an inertial coordinate system. Based on the second position data and the second transformation data, inertial position data is determined that specifies a position of the object in the inertial coordinate system.

Abstract: The invention relates to a medical registration apparatus (1), comprising •two flanks (2a, 2b); •a pivot portion (3) around which at least one of the flanks (2a, 2b) is rotatable with respect to a rotation centre (3c, 3d) (FIG. 1, FIG. 3); •a contacting portion (4a, 4b) on each of the flanks (2a, 2b), each contacting portion (4a, 4b) being spaced apart from the rotation centre (3c, 3d); and •a sensor (5, 6) being arranged with an offset (r, FIG. 4 A) to a line (a) connecting the contacting portions (4a, 4b). The invention also relates to a data processing method for use with the medical registration apparatus.

Abstract: A data processing method for determining the position of a main plane of an anatomical body part, comprising the steps of: • providing absolute auxiliary point data which describe the position of at least one actual auxiliary point of the body part relative to a marker device attacked to the body part, the at least one actual auxiliary point being outside the main plane; • providing relative point data which constrain the possible positions of the main plane relative to the at least one actual auxiliary point; • providing absolute main point data which describe the position of one or two actual main points of the body part relative to the marker device attached to the body part, said one or two actual main points lying in the main plane and/or calculating the position of at least one virtual main point relative to the marker device, said at least one virtual main point being in the main plane and being calculated based on the absolute auxiliary point data and the relative point data; • calculating a position

Abstract: A medical marker (12) device for detection by a navigation system in a navigated medical procedure, comprising: a) an image-detectable two-dimensional marker pattern (13) for detection by an imaging unit of the navigation system; b) a carrier part (14) for carrying the marker pattern (13); c) a positioning part (15) for positioning the marker device (12) on an anatomical structure (11); and d) a support part (16) for supporting the carrier part (14) and the positioning part (15).

Abstract: A data processing method for determining the positional information of characteristic points of a leg, the method comprising the following steps performed by a computer: a) acquiring, by detecting via a hand-held device a stationary reference (R3) and at least one further information, at least four different positions of the femur (F), wherein the pelvis within which the femur (F) can turn is stationary with respect to the stationary reference (R3) and the femur (F) is in a different position each time a positional information value of the femur (F) is acquired; b) determining from the at least four different acquired positional information values of the femur (F) the position of the center of rotation (COR) of the femoral head in relation to a femur reference (R1, R4); c) acquiring a femur information by detecting via a hand-held device a femur reference (R1), and at least one further information; d) determining from the femur information and the at least one further information acquired in step c) the dista

Abstract: A data processing method, performed by a computer, for determining a leg length difference and a leg offset difference of a patient's leg including a femur connected to a pelvis, comprising the steps of: —determining a first landmark vector between a femoral landmark and a second landmark at a first point in time; —determining a second landmark vector between the femoral landmark and the second landmark at a second point in time which is later than the first point in time; —calculating an orthogonal projection of the first landmark vector into a sagittal plane and using the direction of the orthogonal projection of the first landmark vector into the sagittal plane as a leg length direction; —calculating a direction which is perpendicular to the sagittal plane and using this direction as a leg offset direction; and —calculating the leg length difference in the leg length direction and the leg offset difference in the leg offset direction from the first landmark vector and the second landmark vector.

Abstract: A data processing method for determining the relative orientation of an object coordinate system of an anatomical object in a global co-ordinate system, comprising the steps of: acquiring a reference direction dataset representing a first reference direction of a line between a first anatomical landmark of a reference object and a second anatomical landmark of the reference object, and a second reference direction of a line between a third anatomical landmark of the reference object and a fourth anatomical landmark of the reference object, wherein the first and second reference directions are given in a reference coordinate system and the reference object corresponds to the anatomical object; acquiring an object direction dataset representing a first object direction of a line between the first anatomical landmark of the anatomical object and the second anatomical landmark of the anatomical object, and a second object direction of a line between the third anatomical landmark of the anatomical object and the f

Abstract: A data processing method for determining the position of a main plane of an anatomical body part, comprising the steps of: • providing absolute auxiliary point data which describe the position of at least one actual auxiliary point of the body part relative to a marker device attacked to the body part, the at least one actual auxiliary point being outside the main plane; • providing relative point data which constrain the possible positions of the main plane relative to the at least one actual auxiliary point; • providing absolute main point data which describe the position of one or two actual main points of the body part relative to the marker device attached to the body part, said one or two actual main points lying in the main plane and/or calculating the position of at least one virtual main point relative to the marker device, said at least one virtual main point being in the main plane and being calculated based on the absolute auxiliary point data and the relative point data; • calculating a position

Abstract: A data processing method for determining the position of a main plane of an anatomical body part, comprising the steps of: ·providing absolute auxiliary point data which describe the position of at least one actual auxiliary point of the body part relative to a marker device attached to the body part, the at least one actual auxiliary point being outside the main plane; ·providing relative point data which constrain the possible positions of the main plane relative to the at least one actual auxiliary point; ·providing absolute main point data which describe the position of one or two actual main points of the body part relative to the marker device attached to the body part, said one or two actual main points lying in the main plane and/or calculating the position of at least one virtual main point relative to the marker device, said at least one virtual main point being in the main plane and being calculated based on the absolute auxiliary point data and the relative point data; ·calculating a position of t

Abstract: The invention relates to two methods for reading and two methods for storing data, and also to an apparatus for compressing data and decompressing data which are provided for storage by a computer system 51 on a bulk memory 60 of the random access type, which computer system provides the data for storage on a bulk memory on the basis of the rules of a file system, where the data are organized in data blocks, where the data blocks contain organization information for managing the data blocks and contain the user information which is to be stored, where cohesive user information areas can be distributed over a plurality of data blocks which are then concatenated to one another using their organization information.

Abstract: A data memory for storing data, having a memory cell array (2), which comprises a large number of memory cells (3), each of which can be addressed by means of a memory cell select transistor (4) connected to a word line (9) and to a bit line (13) and which have a storage capacity for storing one data bit, the memory cell array (2) containing redundant memory cells (3′), which are provided in order to replace memory cells (3) which have been produced wrongly, by means of readdressing, and having read amplifiers (22), which are in each case provided for the signal amplification of a data bit read from an addressed memory cell (3) via an associated bit line (13) and are supplied with a buffered supply voltage, the redundant memory cells (3′) which have not been readdressed being connected to the associated bit lines (13′) and additionally buffering the supply voltage for the read amplifiers (22).

Abstract: The invention provides a method in which a binary memory cell signal from a; least one memory cell is applied to at least one bit line pair (201t, 201b), the binary memory cell signal from the memory tell is switched through via the bit line pair (201t, 201b) to at least one sense amplifier (202), a binary output signal of the sense amplifier (202) is switched through to a local data line pair (205) as a binary intermediate signal, the binary intermediate signal on the local data line pair (205) is switched through to at least one main data line pair (208) by means of a main data line switching transistor pair (209) in a manner dependent on a row control signal fed via a row control line (210), the main data line switching transistor pair (209) being arranged in the through-plating regions formed between the memory cell arrays.

Abstract: Method for storing data, method for reading data, apparatus for storing data and apparatus for reading data

Abstract: A method for producing circuit structures on a semiconductor substrate is described. Photoresist structures are formed, which define functional circuit structures and dummy circuit structures, whereby the dummy circuit structures which are smaller than a minimum structural size are joined to an additional second dummy circuit structure. The additional circuit structure is provided in such a way that the minimum structural size, which is determined by a smallest required joint surface of the photoresist on the substrate, is exceeded. A semiconductor circuit is also provided, which includes functional circuit structures and dummy circuit structures, the dummy circuit structures being joined to the additional dummy circuit structures.

Abstract: The present invention provides an integrated circuit with a plurality of active strip-shaped regions (S1, D1, S2, D2, S3) arranged in parallel next to one another; a contact level (K2) with a respective plurality of contacts (9′; 11, 12) arranged regularly in the longitudinal direction of the individual strip-shaped regions (S1, D1, S2, D2, S3); the contacts (9′; 11, 12) being arranged in the widthwise direction of the individual strip-shaped regions (S1, D1, S2, D2, S3) in such a way that the widthwise extent of corresponding contacts (9′; 11, 12) of neighboring regions varies.