Abstract: A method is disclosed for adapting treatment coordinates for a treatment of an eye with an ophthalmological laser of a treatment apparatus. The treatment apparatus includes a contact element for fixing the eye. The method includes acquiring at least a first image of the eye, before the eye is fixed by the contact element, and determining treatment coordinates of the eye by means of the first image, determining orientation points of the eye and the position thereof in the first image; acquiring a second image of the eye, after the eye has been fixed by the contact element, wherein the position of the respective orientation points is determined in the second image. The method also includes determining a transformation matrix based on the respectively determined positions of related orientation points in the first and the second image, and adapting (S18) the treatment coordinates by the determined transformation matrix.

Abstract: The invention relates to a method for providing control data for presbyopia reversion for an ophthalmological laser (12) of a treatment apparatus (10). As steps, the method includes determining (S10) presbyopia correction data for presbyopia correction of a cornea (16), wherein an originally uniform visual acuity of the cornea (16) is changed into multifocal areas by application of the presbyopia correction data, wherein the presbyopia correction data is stored in a database (24); retrieving (S12) the stored presbyopia correction data of the cornea (16) from the database (24), if the multifocal areas of the cornea (16) are to be adapted or cancelled at a subsequent point of time; determining (S14) control data for adapting or cancelling the multifocal areas depending on the retrieved presbyopia correction data; and providing (S16) the control data for controlling the ophthalmological laser (12) of the treatment apparatus (10).

Abstract: The invention relates to a method for controlling a laser (18) for the separation of a volume body (12) with an anterior interface (16) and with a posterior interface (14): determining a depth relief (48) of the volume body (12) to be generated between the anterior interface (16) and the posterior interface (14); determining a reference point (52) of an axis of symmetry of the determined depth relief (48) or of a respective interface (14, 16) by means of the control device (20); controlling the laser (18) starting from the determined reference point (52) in tracks circle-like at least in certain areas such that it emits pulsed laser pulses in a shot sequence in a predefined pattern into the material, wherein the interfaces are generated by means of an interaction of the individual laser pulses with the cornea (44) by the generation of a plurality of cavitation bubbles (40) along the circle-like tracks.

Abstract: Method for controlling an eye surgical laser of a treatment device for the separation of a volume body with a predefined posterior interface and a predefined anterior interface from a human or animal cornea. The method includes controlling the laser by means of a control device of the treatment device such that it emits pulsed laser pulses in a shot sequence in a predefined pattern into the cornea. The interfaces of the volume body are defined by the predefined pattern and are generated by means of an interaction of the individual laser pulses with the cornea by the generation of a plurality of cavitation bubbles by photodisruption along at least one cavitation bubble path. At least a partial area of an outer cavitation bubble path of the volume body is generated with a higher cavitation bubble density than an inner cavitation bubble path.

Abstract: A method for controlling an eye surgical laser is disclosed for the separation of a volume body. The method includes determining a target position of a pupil relative to a laser beam and determining an optical zone with a treatment center on interfaces relative to an optical axis of the laser beam, determining a transition zone at the volume body as an extension of the interface, capturing a current actual position of the pupil, determining a deviation between the target position and the actual position, and decentering the determined optical zone relative to the optical axis depending on the determined deviation such that the edge of the volume body is generated concentrically to the optical axis and the optical zone is generated concentrically to the determined treatment center and within the transition zone. Further disclosed are a treatment apparatus, a computer program and computer-readable medium capable of performing the method.

Abstract: A method is disclosed for controlling an eye surgical laser for the separation of a volume body with predefined interfaces from a human or animal cornea. The method includes controlling the laser by means of a control device such that it emits pulsed laser pulses in a predefined pattern into the cornea, wherein the interfaces of the volume body to be separated are defined by the predefined pattern and a surface of the cornea and the interfaces located in the cornea are generated by photodisruption. A treatment device is also disclosed that includes at least one eye surgical laser for the separation of a predefined corneal volume with predefined interfaces of a human or animal eye by photodisruption, and at least one control device for the laser or lasers, which is formed to execute the steps of the method.

Abstract: The invention relates to a method for preparing a material processing apparatus (10) for material processing of an object, wherein a contact element (20) to be fitted onto the object is attached to the material processing apparatus (10), wherein the contact element (20) is transparent to processing laser radiation, comprises a contact surface (22) on its side to be fitted onto the object, and an entry surface (24) on its side facing the material processing apparatus, wherein a shape of the contact surface (22) and/or entry surface (24) is determined by means of radiation of measurement laser radiation (14) before processing the object, in that the measurement laser radiation (14) is focused on the contact surface (22) and/or the entry surface (24) by means of the variable focus adjusting device (18), wherein radiation backscattered or back-reflected from the focus of the measurement laser radiation (14) is confocally detected and thus a position of intersections on the contact surface (22) and/or entry surfac

Abstract: A method is disclosed for determining a current position of an eye of a patient relative to an optical axis of a laser beam of a treatment apparatus. The method includes presetting a criterion characterizing the eye, determining a first target position of the eye relative to the optical axis, positioning a patient interface in a preset area in front of the optical axis, illuminating the eye during an approaching procedure of the patient interface to the eye, capturing a Purkinje image, which is associated with a cornea of the eye, by means of an optical capturing device during the approaching procedure, comparing the captured Purkinje image to the optical axis and determining the current position of the eye depending thereon, comparing the current position to the target position and with a deviation, outputting a control signal to a control device of the treatment apparatus.

Abstract: An apparatus and method are disclosed for providing control data for a laser of a treatment apparatus for the correction of a cornea. The method includes determining a look-up table for preset corneal parameters by a corneal deformation model, wherein the cornea can be modeled in deformed and non-deformed states by the corneal deformation model. A value of at least one preset corneal parameter in the non-deformed state of the cornea is varied and an effect of this variation on values of the corneal parameters in the deformed state of the cornea is ascertained for determining the look-up table. The method further includes ascertaining a corneal value to be achieved from predetermined examination data, determining by the look-up table a deformation-corrected corneal value to be achieved for compensating for the deformation of the cornea, and providing control data, which uses the deformation-corrected corneal value for correcting the cornea.

Abstract: The invention relates to a method for providing control data for a laser (18) of a treatment apparatus (10) for the correction of a cornea (26), including ascertaining (S10) an effect of a deformation of the cornea (26) on preset corneal parameters by means of a corneal deformation model, wherein the cornea (26) can be modeled in a deformed and non-deformed state by the corneal deformation model, wherein values of preset corneal parameters in the non-deformed state of the cornea (26) are varied and the effect of this variation on values of the corneal parameters in the deformed state of the cornea (26) is ascertained for determining the effect of the deformation; determining (S12) the most important corneal parameters for a treatment and/or deformation of the cornea (26) depending on a magnitude of the ascertained effect; adapting (S14) at least one preset fit function as the compensation function of the deformation to the values of the most important corneal parameters; calculating (S16) a deformation-correc

Abstract: A method for providing control data for an eye surgical laser of a treatment apparatus for removing tissue is disclosed. The method includes utilizing a control device for determining a corneal geometry and an ocular wavefront of a human or animal eye from predetermined examination data. A corneal wavefront is then determined from the corneal geometry using a physical model, and an internal wavefront is calculated from a difference between the ocular wavefront and the corneal wavefront. A wavefront to be achieved is calculated from a difference of a preset target wavefront and the calculated internal wavefront. A target corneal geometry is determined from the wavefront to be achieved by the physical model, and a tissue geometry to be removed is calculated from a difference of the corneal geometry and the target corneal geometry, and control data for controlling the eye surgical laser is provided.

Abstract: The invention relates to a treatment apparatus for an eye treatment, at least comprising: at least one laser beam source configured for emission of laser pulses, at least one beam exit device, which is configured to pass the respective laser pulses with a predetermined laser pulse cross-sectional profile to respective impingement positions in a treatment surface of a preset treatment volume of an eye to be treated, a control device, which is configured to ascertain coordinates of the respective impingement positions in the treatment surface according to at least two predetermined coordinate ascertaining methods for the preset treatment volume and the predetermined laser pulse cross-sectional profile.

Abstract: A method is disclosed for providing control data for an eye surgical laser of a treatment apparatus for the removal of a tissue. The method includes using a control device for determining a wavefront of a cornea and Zernike polynomials from the wavefront and calculating a respective tissue geometry for each Zernike polynomial. A combination of Zernike polynomials describes a tissue removal geometry. The control device ascertains a subgroup of the Zernike polynomials by an optimization calculation, which uses a preset condition to select Zernike polynomials. The condition is preset by a maximized target corneal geometry and a target imaging correction to be achieved. The target corneal geometry is a difference between a corneal geometry and the tissue removal geometry. An optimized tissue removal geometry is found using the subgroup and control data for controlling the eye surgical laser, which uses the optimized tissue removal geometry for separating the tissue.

Abstract: The invention relates to a method for controlling a laser (12) of a laser device (10) and/or to a method for performing a surgical procedure comprising at least the steps of: generating laser pulses (40) with a first energy density (42) below a photodisruption regime of a polymer material (26) of a region (16) of an optical element; irradiating a core region (30) with the laser pulses (40), wherein a refractive index of the polymer material (26) changes depending thereon; generating first irradiation lines (34) within the core region (30) and generating a first optical correction (44) in the core region (30); generating laser pulses (40) with a second energy density (46) below a photodisruption regime; irradiating an edge region (36) with the laser pulses (40), wherein the refractive index of the polymer material (26) changes depending thereon; and generating second irradiation lines (38) within the edge region (36) and generating a second optical correction (48) in the edge region (36).

Abstract: The invention relates to a method for providing control data of a laser device (10) for the non-destructive laser-induced property change of a polymer structure (14). As steps, the method includes ascertaining (S10) a respective irradiation parameter range for preset irradiation parameters of the laser device (10) by means of an irradiation model, wherein a property change model is provided in the irradiation model, in which a caused property change of the polymer structure (14) is modelled depending on the irradiation parameters, wherein a destruction threshold value model is provided in the irradiation model, in which at least one threshold value for a laser-induced optical breakthrough of the polymer structure is modelled depending on the irradiation parameters, and wherein the caused property change from the property change model is optimized while limiting by the threshold value from the destruction threshold value model for ascertaining the irradiation parameter ranges.

Abstract: The invention relates to a treatment apparatus (1) for an eye treatment, at least comprising: at least one laser beam source (3) configured for emission of a laser beam (2), at least one beam exit device (9), which is configured to direct the laser beam (2) to an eye (11) to be treated, at least one transfer optics (6), which is configured to feed the laser beam (2) along a respective optical path (21) to the at least one beam exit device (9), and a control device (14), which is configured to retrieve a predetermined eye treatment configuration (15) from a storage device (13), on which multiple eye treatment configurations (12) are stored, to adjust the at least one laser beam source (3) for generating the laser beam (2) of a pulse duration (4) to be adjusted according to the predetermined eye treatment configuration (15) of the eye treatment configurations (12), and to adjust the at least one transfer optics (6) for providing a predetermined numerical aperture (10) of the transfer optics (6) according to the

Abstract: A method of controlling an eye surgical laser is disclosed for the separation of a volume body with predefined posterior and anterior interfaces from a human/animal cornea. The method including controlling the laser with a control device, the laser being configured to emit pulsed laser pulses in a predefined pattern into the cornea. The posterior and anterior interfaces of the volume body are defined by the predefined pattern and are generated by an interaction of the individual laser pulses with the cornea through photodisruption. The control device controls the laser beam such that both interfaces are generated via a continuous, uninterrupted sequence of laser pulses. A treatment device is disclosed with at least one eye surgical laser for the separation of a predefined corneal volume with predefined interfaces of a human/animal eye by photodisruption and with at least one control device for the laser(s).

Abstract: The invention relates to a method for controlling a laser (12) of a treatment apparatus (10), comprising the steps of: generating a plurality of laser pulses (34) with a predefined energy below a photodisruption regime of a polymer material (26), irradiating the area (16) with the laser pulses (34), wherein a refractive index of the polymer material (26) changes at the irradiated irradiation point (36) depending thereon, generating a first irradiation line (38) in a first depth plane (40), wherein the first depth plane (40) is formed substantially perpendicularly to an optical axis (20) of the area (16), generating a second irradiation line (42) in a second depth plane (44) different from the first depth plane (40), wherein the first depth plane (40) and the second depth plane (44) overlap at least in certain areas viewed in the direction of the optical axis (20) and the second depth plane (44) is formed substantially perpendicularly to the optical axis (20).

Abstract: The invention relates to a method for controlling an eye surgical laser (18) for removing a volume body (12) from a cornea (44) with an anterior interface (16) of the cornea (44) and a posterior interface (14) of the cornea (44), comprising the steps of: presetting the posterior actual interface (14); determining a first imaging point (48) of the cornea (44); determining an anterior target interface (46) depending on the posterior actual interface (14) and the first imaging point (48) based on a mathematical model (M); determining a shape of the volume body (12) to be generated by presetting the determined anterior target interface (46); and generating control data for generating the volume body (12) such that the anterior actual interface (16) corresponds to the determined anterior target interface (46) after removing the volume body (12) from the cornea (44). Further, the invention relates to a treatment apparatus (10), to a computer program product as well as to a computer-readable medium.

Abstract: The invention relates to a method for providing control data for an eye surgical laser of a treatment apparatus for the removal of a tissue from a human or animal cornea.