WO2023057353A1 - Device and method for characterising a laser beam of an ophthalmic laser system - Google Patents

Abstract

Disclosed are a method and a device (10) for characterising a laser beam (12) of an ophthalmic laser system (14). The device (10) comprises a contact element (16) by means of which the device (10) can be coupled to the ophthalmic laser system (14) such that the laser beam (12) can be coupled into the device (10) via a transmission lens (28) of the ophthalmic laser system (14) and via the contact element (16). The device (10) further comprises an optical collimation unit (18) which is designed to at least partially collimate the laser beam (12) coupled into the device (10) via the contact element (16), and a wavefront sensor (20) which is designed to determine a wavefront of at least part of the collimated laser beam (12). A laser system (14) and use of a wavefront sensor (20) are also disclosed.

Description

DEVICE AND METHOD FOR CHARACTERIZING A

LASER BEAM OF AN OPHTHALMIC LASER SYSTEM

An apparatus for characterizing a laser beam of an ophthalmic laser system, an ophthalmic laser system, a method for characterizing a laser beam of an ophthalmic laser system and a use of a wavefront sensor are provided. The embodiments are thus particularly in the field of ophthalmic laser systems and refractive surgery.

For the treatment of the cornea of a patient's eye using an ophthalmic femtosecond laser system, the cornea is usually docked onto a planar or spherical contact glass. The contact glass fixes the patient's eye or the cornea mechanically and allows the laser beam to pass through and be applied to the cornea. In this case, the laser beam is typically focused on a desired point in a processing area of the laser beam on or in the cornea, so that the cornea is acted upon in the focus. For the desired treatment, the laser focus is then moved three-dimensionally over the treatment area in the processing area using transmission optics of the ophthalmic laser system and scanners in order to generate the desired cut surfaces in the cornea using the spatially offset foci. The treatment area is defined by the contact lens and is below the contact lens in the cornea. The cornea has a refractive index of approximately 1.336. Contact glasses are typically designed for one-time use and are therefore usually reattached to the device for each treatment. The contact glass is typically attached by suction using a vacuum.

Alternatively, another mechanical connection, for example by means of a bayonet lock, can be used to couple the contact lens to the ophthalmic laser system. The size and quality of the laser focus is often decisive for the separability of the corneal tissue. In order to achieve a satisfactory treatment result, a focus with a diameter of 10 μm or less or even 5 μm or smaller is typically required. The size of the laser focus is usually dependent on the properties of the laser system's laser source and the relay optics, such as the numerical aperture and/or aberrations of the relay optics, such as astigmatism or coma. In the case of complex optical systems in particular, the quality of the focus can depend on the location in the treatment area. Achieving and reliably maintaining a focus of appropriate and defined size and quality is therefore of key importance.

It is therefore the underlying object to provide a device and a method that enable simple and reliable characterization of the laser beam.

The object is achieved by a device and a method for characterizing a laser beam of an ophthalmic laser system, an ophthalmic laser system and a use with the features of the respective independent claims. Optional refinements are specified in the dependent claims and in the description.

A first embodiment relates to a device for characterizing a laser beam of an ophthalmic laser system. The device comprises a contact element, by means of which the device can be coupled to the laser system in such a way that the laser beam can be coupled into the device via transmission optics of the ophthalmic laser system and via the contact element. In addition, the device includes a collimating optics which is designed to at least partially collimate the laser beam coupled into the device via the contact element. In addition, the device includes a wavefront sensor which is designed to determine a wavefront of at least part of the collimated laser beam. Another embodiment relates to a method for characterizing a laser beam of an ophthalmic laser system. The method includes providing a device for characterizing the laser beam, which has a contact element, collimation optics and a wavefront sensor. The method also includes coupling the device for characterizing the laser beam to the ophthalmic laser system using the contact element in such a way that the laser beam emitted by transmission optics of the ophthalmic laser system is coupled into the device via the contact element. In addition, the method includes collimating the coupled-in laser beam using the collimation optics and determining a wavefront of the collimated laser beam using the wavefront sensor.

A further embodiment relates to an ophthalmic laser system comprising a device for characterizing a laser beam according to an embodiment.

A further embodiment relates to the use of a wavefront sensor to characterize the focus of a laser beam of an ophthalmic laser system.

An ophthalmic laser system is a laser system for the refractive surgical treatment of a patient's eye, in particular the cornea. In particular, the ophthalmic laser system can comprise a laser source and also one or more optical elements in order to apply the laser beam provided by the laser source to the patient's eye. In addition, the ophthalmic laser system includes transmission optics to which either a contact glass for fixing a patient's eye or a contact element of a disclosed device can be coupled. The ophthalmic laser system is designed in particular to apply the laser beam to the patient's eye through the transmission optics and a contact glass. Furthermore, it can ophthalmic laser system have a deflection device or a scanner to deflect the laser beam and to apply it to different positions of the processing area along different beam paths through the transmission optics and the contact glass or a contact element of a device according to one embodiment. An ophthalmic laser system is also referred to as a laser system within the scope of the present disclosure. The transmission optics is an optical element on which the laser beam is decoupled from the ophthalmic laser system. The transmission optics can be designed in such a way that they enable a contact glass and/or a contact element to be coupled. The ophthalmic laser system optionally includes a laser source for providing the laser beam. Optionally, the laser source can be designed as a femtosecond laser source.

The characterization of the laser beam includes in particular the characterization of one or more beam parameters of the laser beam. In particular, the characterization of the laser beam can include a characterization of the focus of the laser beam. The focus is provided by the ophthalmic laser system and is optionally provided for the treatment of the patient's eye. The characterization of the laser beam can in particular include the characterization of the size and/or quality of the focus. A diameter of the focus, for example, or a diameter of the region of the focus in which the intensity of the focus has at least a value of 1/e of the maximum intensity, can be determined as the size of the focus. The quality of the focus, for example, can be determined by its agreement or deviation from a Gaussian intensity profile. Alternatively or additionally, the quality of the focus can be determined based on the presence or absence of possible aberrations, which can be described, for example, by Zernike polynomials.

In this case, a contact element is an optical element which can be coupled to the laser system and is coupled in by the laser system provided and emitted via the transmission optics laser beam allows in a device according to an embodiment. The contact element is therefore designed in such a way that it enables the laser beam to be coupled into the collimating optics. In particular, the contact element can be designed in such a way that it can also be coupled to the ophthalmic laser system, like a contact lens for fixing a patient's eye. A conventional contact glass can, but does not necessarily have to be made of glass, but can also be made of another material that is transparent to the laser beam, for example a plastic material. A contact element can also be made from a material that is transparent to the laser beam, in particular from glass and/or a plastic material. In particular, the contact element can be designed in such a way that it has a contact surface which is identical or similar to the contact surface of contact glasses which is provided with the same ophthalmic laser system for treating the eye.

In particular, the contact element can be designed in such a way that it has the same or very similar optical properties as the contact glasses provided for fixing a patient's eye. As a result, the focus in the device of the laser beam can be provided in the same way or as similar as possible to that focus as is present when using a contact glass in a patient's eye fixed thereto. In other words, the contact element is optionally designed in such a way that, with regard to the focusing of the laser beam, it has the same properties as possible as a contact lens provided for fixing the patient's eye. If different contact glasses are provided for use with the laser system, a corresponding contact element can optionally be provided separately for each of the different contact glasses.

The collimation optics is an optical element which is designed to collimate the laser beam, which is focused and coupled out by the transmission optics of the laser system and coupled into the device through the contact element, after the focus. Alternatively, the Collimation optics comprise or consist of an arrangement of several optical elements. In other words, the collimation optics are designed to convert the divergent laser beam into an approximately plane-parallel bundle of rays after the focus. The fact that the collimating optics are designed to at least partially collimate the laser beam means that perfect collimation does not necessarily have to be achieved, but that incomplete collimation can optionally also be carried out. According to an optional embodiment, however, the collimation optics are designed in such a way that they cause the laser beam to be collimated as completely as possible. Optionally, a part of the laser beam can be coupled out before collimation by means of a beam splitter, in order to reduce the intensity of the laser beam, for example.

A wavefront sensor is a sensor that enables the wavefront of the collimated laser beam to be determined. For example, the wavefront sensor can be designed as a Shack-Hartmann sensor or include one. The wavefront sensor can optionally have a microlens array and a CCD array and/or CMOS array arranged behind it in order to be able to determine a spatial distribution of the propagation direction of the wavefront.

The embodiments offer the advantage that a device is provided which can be made compact. This offers the advantage that the device can be arranged where the head or the patient's eye is positioned for an intended treatment. In other words, the device can be constructed structurally in such a way that it can be arranged relative to the laser system at an intended position of a patient's eye to be treated. This in turn offers the advantage that the laser beam can be characterized in the same position and/or operational state that is used in the treatment of the patient's eye. Furthermore, this offers the advantage that the device can be designed to be transportable can and thus carrying the device is facilitated by a service technician.

The embodiments also offer the advantage that the device can be coupled to the laser system in the same or similar manner as contact glasses for fixing a patient's eye can be fixed to the laser system. This offers the possibility to characterize the laser beam under the same or very similar conditions that would prevail with coupled contact glass.

In addition, the embodiments offer the advantage that the characterization can be carried out in a simple manner and therefore no high demands have to be made on the technical knowledge of the operating personnel. In particular, the embodiments offer the possibility of achieving correct positioning and/or orientation of the device relative to the laser system by coupling the device to the laser system, without this requiring further intervention by the operator to align the device. Optionally, a partially or fully automated self-adjustment of the device can also be provided in the coupled state, in which the device aligns itself with the focus of the laser beam. This can further simplify the characterization of the laser beam.

According to an optional embodiment, coupling the device to the ophthalmic laser system includes coupling the contact element to the transmission optics. The coupling of the contact element to the transmission optics can optionally include suction and/or mechanical locking, for example by means of a bayonet lock. This offers the advantage that the contact element can be reliably fixed to the laser system or to the transmission optics. This also enables the contact element to be attached to the laser system in a very similar or identical manner to a contact glass used for the treatment. The coupling of the device to the ophthalmic laser system can accordingly in particular comprise mechanical coupling in which the device is fixedly connected to the ophthalmic laser system at a predetermined position. The mechanical coupling can take place in the same or a similar way as the coupling of a contact glass, which is used during an operation as a patient interface between a patient's eye to be treated and the ophthalmic laser system. In addition, the predetermined position at which the device is coupled to the ophthalmic laser system can be predetermined such that the device is coupled to the ophthalmic laser system in the same position and/or orientation as a contact glass or patient interface is coupled to the ophthalmic laser system . This can offer the advantage that the laser beam of the ophthalmic laser system can be coupled into the device in the same way as is the case with a coupled contact glass or patient interface. This makes it possible for the laser beam to have the same properties during characterization as when the laser beam is applied to the eye, or for any deviations therefrom to be as small as possible. As a result, a particularly reliable characterization of the laser beam can take place. In addition, the properties of the laser beam can optionally be determined in the form in which they actually exist during the treatment of an eye.

At the interface or side to be coupled to the ophthalmic laser system, the contact element can resemble a contact glass, which serves as a patient interface, or can be designed identically to one. This offers the advantage that the laser beam can be coupled into the device in the same way as is the case in a contact glass. On the other hand, the contact element can differ from a contact glass in other aspects. For example, the contact element of the device can have a planar or planar shape on a side facing away from the ophthalmic laser system in the coupled state, whereas a contact lens can have a concave shape on the side facing away from the ophthalmic laser system, which at least partially matches the shape of a Eye can be adjusted. In other words, a similarity of the contact element of the device with a contact glass, which can serve as a patient interface for an operation, can be limited to a side facing the ophthalmic laser system in the coupled state. Furthermore, the contact element of the device can optionally be set up to characterize the laser in such a way that it is present in the device in air, whereas the focus is present in an aqueous environment when using a contact glass in an eye fixed thereto. Any deviations that may result from this can optionally be taken into account by the device when characterizing the laser beam.

According to an optional embodiment, at least the contact element, the collimation optics and the wavefront sensor together form a sensor assembly. In particular, the sensor assembly can form a structural unit. This offers the advantage that the sensor assembly can be fastened to the laser system via the contact element and the collimation optics and the wave front sensor are thus fastened equally to the laser system and to the transmission optics. Furthermore, this offers the advantage that the sensor assembly consisting of the contact element, collimation optics and wavefront sensor can be provided in a particularly compact form. This makes it easier to arrange the device at that position at which the positioning of the head or the patient's eye is intended during the treatment.

According to a further optional embodiment, the sensor assembly has an extension along the optical axis of the collimation optics of no more than 15 cm. This enables a particularly compact configuration of the device.

According to an optional embodiment, the device further includes a support member configured to support the sensor assembly. In particular, the support element can be designed to be placed on or arranged on a treatment table on which the patient's head is placed during treatment. Alternatively or additionally the support element can be designed in such a way that the support element can be fastened to the laser system and optionally to its transmission optics in order to carry the sensor assembly. In other words, the support element can form a base for the sensor assembly, which enables the device and in particular the sensor assembly to be positioned stably below or in direct proximity to the transmission optics. Optionally, the sensor assembly can be arranged on and/or in the support element in such a way that the sensor assembly and in particular the contact element is accessible from above and is free for coupling to the transmission optics. Optionally, part of the sensor assembly and in particular the contact element can protrude from the top of the support element.

According to an optional embodiment, the support element is designed to carry the sensor assembly in such a way that the effort required for coupling the device to the laser system, in particular for sucking the contact element onto the transmission optics of the laser system, is reduced. For example, the support element can exert a repulsive and/or attractive force on the sensor assembly in the direction of the transmission optics. For this purpose, for example, the device can have a spring element which exerts a spring force on the sensor assembly and the support element and in this way presses the sensor assembly and the support element apart. The device can have provisions, in particular structural ones, which prevent the sensor assembly from becoming detached from the support element and falling out of it. Such configurations offer the advantage that the support element can support the sensor assembly being pressed against the laser system and in particular against the transmission optics. This offers the advantage that the force required for any suctioning of the contact element to the transmission optics is reduced and accordingly such sensor assemblies and/or devices can also be fixed to the transmission optics by suction in the same or similar manner as conventional contact glasses, although the Weight of the device and / or the sensor assembly is greater than that of conventional contact glasses. According to an optional embodiment, the device also includes a displacement device which is designed to displace the collimation optics and optionally the wavefront sensor relative to the contact element at least perpendicularly to the optical axis. “At least perpendicular to the optical axis” means that the collimation optics and/or the wavefront sensor can be displaced perpendicularly to the optical axis and can optionally also be displaced along a direction parallel to the optical axis. The displacement device can also optionally have both perpendicular and parallel directional components relative to the optical axis of the collimation optics. The displacement device offers the advantage that the laser beam and in particular the focus can be characterized at different positions in the processing area of the laser beam. As a result, any deviations in the size and/or quality of the focus at different positions in the processing area can be determined and characterized. In particular, the focus can be provided at different positions of the processing area in that the laser system with an integrated deflection device emits the laser beam on different beam paths through the transmission optics. As a result, when the device is coupled, the laser beam passes through the contact element on different beam paths. In order to characterize the laser beam and in particular the focus at the different positions, the displacement device enables the collimation optics and optionally the wavefront sensor to be tracked so that the focus area of the collimation optics again coincides with the position of the focus of the laser beam and the laser beam is accordingly collimated by the collimation optics . The device can be set up so that the collimation optics and optionally the wavefront sensor are tracked by the displacement device as a function of the beam path specified by the deflection device. In other words, the displacement device and deflection device can be synchronized or otherwise coordinated with one another. The device can be designed in such a way that moving the collimation optics and optionally the Wavefront sensor takes place within the sensor assembly without the contact element moves relative to the laser system. For this purpose, in particular, the displacement device can be integrated into the sensor assembly. According to an optional embodiment, the collimating optics and the wavefront sensor are displaced in the same way, so that there is no relative movement between the collimating optics and the wavefront sensor. This offers the advantage that the wavefront sensor data recorded at different positions can be compared with one another. According to other optional embodiments, a relative movement between the collimation optics and the wavefront sensor can take place, for example by only displacing the collimation optics but not the wavefront sensor. In such embodiments, the relative displacement can be taken into account when evaluating the data from the wavefront sensor in order to make the measurement data from different positions in the processing area comparable.

According to an optional embodiment, the collimation optics have a microscope objective or are designed as such. This offers the advantage that an effective widening and collimation of the laser beam can be achieved after the focus. This offers the further advantage that the collimation optics can be provided in an extremely compact form, as a result of which the installation space of the device can be kept particularly small. This is of great advantage in particular for attaching the device to the position at which the patient's head is arranged during an intended treatment. This also makes it easier to transport the device, since the collimation optics are provided in a particularly compact and robust design. The microscope objective can optionally be designed as an immersion objective, in which an immersion film, for example made of water or oil, is formed between the front lens of the immersion objective and the contact glass. In this case, when evaluating the data from the wavefront sensor, i.e. when characterizing the laser beam and/or the focus, the immersion can be taken into account in order to achieve a correct result, which is important in the event of a treatment using a cognac glass to fix the patient's eye is meaningful without immersion. Alternatively, a microscope objective that does not provide for immersion can optionally be used. For example, in such optional embodiments, an air layer can be formed between the contact glass and the front lens of the microscope objective. A contact element which has a flat surface facing the microscope objective can optionally be used for this purpose.

Alternatively, the collimation optics can be designed differently from a microscope objective. Thus, the collimation optics can optionally be designed in the manner of a microscope objective, but have different dimensions than a microscope objective. The collimation optics can optionally be larger than a conventional microscope lens. Thus, the collimation optics can optionally have or provide a field of view with a diameter of approximately 10 mm, whereas a conventional microscope objective has a field of view with a diameter of approximately 1 mm.

According to an optional embodiment, the device also includes an evaluation unit which is set up to determine at least one of the following properties of the laser beam based on the wavefront of the laser beam determined by the wavefront sensor: beam diameter, beam profile, numerical aperture, wavefront error, focus size. According to another optional embodiment, the device can be connected to an evaluation unit, which, however, does not necessarily form part of the device. For example, the evaluation unit can have a microchip and/or a computing unit. For example, the evaluation unit can have a computer and/or a smartphone or be designed as such or such to which the device can be connected. The connection can be provided, for example, via a cable connection, such as a network cable connection and/or a USB cable connection, and/or be wireless, for example via Bluetooth and/or WIFI. The evaluation unit is optionally set up for this purpose, that of the wavefront sensor Evaluate the data provided and determine one or more properties of the laser beam and in particular the focus on the basis of the data.

According to an optional embodiment, the method includes aligning the device relative to the laser system such that a focal point of the collimation optics coincides with the focus of the laser beam in a processing area or the focus of the laser beam and the focal point of the collimation optics converge. In a state in which the device is docked or coupled to the laser system via the contact element, the collimation optics and optionally the wavefront sensor can be positioned in such a way, for example by means of a displacement device, that the focal point of the collimation optics coincides with the focus of the laser beam. The alignment can optionally be partially or fully automated. This offers the advantage that the use of the device and accordingly the characterization of the laser beam can be simplified. The displacement device can optionally be designed as an eccentric or have one that can move the collimation optics and the wavefront sensor.

According to an optional embodiment, the method further comprises deflecting the laser beam by the ophthalmic laser system such that the focus of the laser beam is directed to at least one further position in a processing area of the laser beam. In addition, according to the optional embodiment, the method includes a displacement of the collimation optics and optionally the wavefront sensor relative to the contact element. The collimation optics and optionally the wavefront sensor are displaced relative to the contact element at least in a plane perpendicular to the optical axis of the collimation optics in such a way that the focal point of the collimation optics coincides with the focus of the laser beam at the at least one further position in the processing area of the laser beam. In addition, the method optionally further includes determining the wavefront of the laser beam at the at least one further position in the processing area of the laser beam. This makes it possible to characterize the laser beam and in particular the focus at different positions in the processing area and to determine any deviations. According to an optional embodiment, the method also includes determining at least one of the following properties of the laser beam based on the wavefront of the laser beam determined by the wavefront sensor: beam diameter, beam profile, numerical aperture, wavefront error, focus size, beam quality, in particular in the form of an M ² value. Optionally, the laser beam is deflected by means of a deflection device of the ophthalmic laser system, and the collimation optics are displaced as a function of the deflection of the laser beam by the deflection device.

The features and embodiments mentioned above and explained below are not only to be regarded as disclosed in the combinations explicitly mentioned in each case, but are also covered by the disclosure content in other technically meaningful combinations and embodiments.

Further details and advantages will now be explained in more detail using the following examples and optional embodiments with reference to the figures.

Show it:

1 shows a device for characterizing a laser beam of an ophthalmic laser system according to an optional embodiment in a schematic representation.

2 shows a device for characterizing a laser beam of an ophthalmic laser system according to a further optional embodiment in a schematic representation. In the following figures, the same or similar elements in the different embodiments are denoted by the same reference numbers for the sake of simplicity.

FIG. 1 shows a schematic representation of a device 10 for characterizing a laser beam 12 of an ophthalmic laser system 14 according to an optional embodiment. The device 10 has a contact element 16, collimation optics 18 and a wavefront sensor 20, which together form a sensor assembly 22. The sensor assembly 22 may include a housing 24 that at least partially encloses the components. The contact element 16 is arranged at the upper end of the sensor assembly 22 and protrudes from the housing 24 and is accessible at the top of the sensor assembly 22 . The collimation optics 18 are designed as a microscope lens 26 and the wavefront sensor 20 as a Shack-Hartmann wavefront sensor. In other embodiments, optional relay optics can additionally be arranged between the collimation optics 18 and the wavefront sensor 20 .

The device is coupled to transmission optics 28 of the ophthalmic laser system 14 by means of the contact element 16 . Optionally, the laser system 14 and/or the device 10 can be designed in such a way that the device 10 can be fixed to the transmission optics 28 of the laser system 14 by sucking on the contact element 16 . The device is optionally coupled to the transmission optics 28 in the same way as a conventional contact glass (not shown) is coupled to the transmission optics 28 for fixing the patient's eye in the case of treatment of a patient's eye. This makes it possible to characterize the laser beam and in particular the focus of the laser beam 12 under the same conditions or conditions that are as similar as possible to those that also prevail when treating a patient's eye using a conventional contact glass. In device 10, contact element 16, collimation optics 18 and wavefront sensor 20 are arranged relative to one another in such a way that a laser beam 12 coupled in via contact element 16 forms a focus 12a in a processing area 1000 below contact element 16, and the focus area of collimation optics 18 forms the focus 12a of the laser beam 12 coincides. The collimation optics 18 can be embodied as an optional microscope objective 26, with a different type of collimation optics 18 also being able to be used according to other embodiments. In other words, the collimation optics 18 embodied as a microscope objective 26 are arranged in such a way that the focus 12a of the laser beam 12 is at the working distance of the microscope objective 26 . The result of this is that the collimation optics 18 or the microscope objective 26 collimates the laser beam 12 after the focus 12a to form a light beam which is as plane-parallel as possible and which then impinges on the wavefront sensor 20 arranged underneath.

The wavefront sensor 20 has a microlens array 30 and an underlying sensor array 32, such as a CCD or CMOS array, by means of which the beam of rays of the collimated laser beam passing through the microlens array is location-dependent depending on the local curvature of the wavefront through the respective micro lens is deflected. From this, the wavefront of the laser beam and optionally other parameters for characterizing the laser beam can then be determined by means of an evaluation unit 34 . In particular, the size and/or quality of the focus 12a can be determined in this way using the data obtained from the wavefront.

In the context of the present disclosure, the directional information “up” and “down” is used merely for illustration purposes, in particular with reference to the figures. Of course, some embodiments can optionally also be used in other orientations, for example horizontally, in which the designations “top” and “bottom” can deviate from the meanings of the terms that are customary in common usage. Furthermore, according to the optional embodiment shown, the device 10 has a support element 36 which carries the sensor assembly 22 and optionally stabilizes it in its position and/or orientation. The support element can have a suitable shape on the underside, which enables the device to be arranged in a stable and positionally secure manner at that position at which the patient's head is arranged in the event of treatment. This allows the contact element 16 to be coupled directly to the transmission optics 28 . According to other optional embodiments, the device 10 can also be provided without the support element 36 . This can be the case in particular when the sensor assembly 22 has a low mass and accordingly no support or carrying of the sensor assembly 22 for coupling to the transmission optics 28 is necessary or advantageous.

Furthermore, the support element 36 has a mechanical spring element 38 which presses the sensor assembly 22 upwards and counteracts the weight of the sensor assembly 22 accordingly. This facilitates coupling when the device 10 is positioned appropriately relative to the laser system 14 . In particular, this can reduce the force required for coupling the contact element 16 to the transmission optics, which is provided, for example, by a suction effect by suction, since the suction effect does not necessarily have to overcome the entire weight of the sensor assembly 22 or even the entire device 10 . Optionally, the spring force can be matched to the weight of the sensor assembly 22 in such a way that the suction force required for the coupling corresponds approximately to the suction force that is used to suck in a conventional cognac glass to fix a patient's eye. According to optional embodiments, the spring element 38 can have or consist of one or more of the following elements: coil springs, leaf springs, air springs, magnetic spring elements.

FIG. 2 shows a device 10 according to a further optional

embodiment. This corresponds in many features to that in Figure 1 presented embodiment, which will not be repeated for the sake of brevity. In this regard, reference is made to FIG. For the sake of clarity, only the sensor assembly 22 of the device 10 is shown. However, the device 10 can also have a support element 36 and an evaluation unit 34 .

Deviating from the embodiment shown in FIG. 1, the device 10 has a displacement device 40 in the sensor assembly 22, which can displace the collimation optics 18 and the wavefront sensor 20 relative to the contact element perpendicularly to the optical axis of the collimation optics. This is indicated schematically by the optical axis of the collimating optics 1002 and the optical axis of the contact element 1004, which, unlike in FIG. For this purpose, the displacement device 40 is set up to displace the collimation optics 18 and the wavefront sensor 20 along a direction or in a plane perpendicular to the optical axis of the contact element 16 , as indicated by arrow 1006 . This offers the possibility of being able to align the collimating optics 18 precisely with the laser beam 12 or the laser focus 12a even if this is not on the optical axis of the contact glass. In particular, this enables the precise alignment to be carried out even though the contact element 16 remains firmly coupled to the transmission optics 28 and these are not moved relative to one another.

Accordingly, this embodiment offers the possibility of precisely collecting and collimating the laser beam 12 at different positions in the processing area 1000 with the collimation optics 16 and correspondingly characterizing the laser beam 12 and the laser focus 12a precisely at different points in the processing area 1000 . In this way, in particular, any deviations in the size and/or quality of the focus 12a at different positions in the processing area 1000 can be determined, which can then be used accordingly when planning a treatment of a patient's eye can be taken into account. As a result, the accuracy of the treatment can be further improved.

reference list

10 Device for characterizing a laser beam

12 laser beam

12a Focus of the laser beam

14 ophthalmic laser system

16 contact element

18 collimating optics

20 wavefront sensor

22 sensor assembly

24 Sensor assembly housing

26 microscope lens

28 transmission optics

30 microlens array

32 sensor array

34 evaluation unit

36 support member

38 spring element

40 displacement device

1000 edit area

1002 optical axis of collimating optics

1004 optical axis of the contact element

1006 shift directions

Claims

22

Device (10) for characterizing a laser beam (12) of an ophthalmic laser system (14), the device (10) comprising:

- a contact element (16) by means of which the device (10) can be coupled to the ophthalmic laser system (14) in such a way that the laser beam (12) via transmission optics (28) of the ophthalmic laser system (14) and via the contact element (16) can be coupled into the device (10);

- a collimation lens system (18) which is designed to at least partially collimate the laser beam (12) coupled into the device (10) via the contact element (16);

- A wavefront sensor (20) which is designed to determine a wavefront of at least part of the collimated laser beam (12). The device (10) of claim 1, wherein coupling the device (10) to the ophthalmic laser system (14) comprises coupling the contact element (16) to the relay optic (28), and wherein coupling the contact element (16) to the relay optic (28) includes suction and/or mechanical locking. Device (10) according to claim 1 or 2, wherein at least the contact element (16), the collimating optics (18) and the wavefront sensor (20) together form a sensor assembly (22) which optionally extends along the optical axis (1002) of the collimating optics (18) of not more than 15 cm. The device (10) of claim 3, further comprising a support member (36) adapted to support the sensor assembly (22). The apparatus (10) of claim 4, wherein the support member (36) is attachable to the laser system (14) and optionally to the relay optics (28) for supporting the sensor assembly (22) and/or for supporting the sensor assembly (22) on a treatment table can be placed and/or arranged. Device (10) according to claim 4 or 5, wherein the support element (36) is designed to carry the sensor assembly (22) in such a way that a for coupling the device (10) to the laser system (14), in particular a for the Suction of the contact element (16) to the transmission optics (28) of the laser system (10), required effort is reduced. Device (10) according to Claim 6, further comprising a displacement device (40) which is designed to move the collimation optics (18) and optionally the wavefront sensor (20) relative to the contact element (16) at least perpendicularly to the optical axis (1002) of the collimation optics ( 18) to postpone. Device (10) according to one of the preceding claims, wherein the collimation optics (18) have a microscope lens (26) or is designed as such. Device (10) according to one of the preceding claims, wherein the device (10) is structurally designed in such a way that it can be arranged relative to the laser system (14) at an intended position of a patient's eye to be treated. Device (10) according to one of the preceding claims, further comprising an evaluation unit (34) which is set up to use the wavefront of the laser beam (12) determined by the wavefront sensor (20) to determine at least one of the following properties of the To determine the laser beam (12): beam diameter, beam profile, numerical aperture, wavefront error, focus size. Ophthalmic laser system (14) comprising a device (10) for characterizing a laser beam (12) according to one of claims 1 to 10. Ophthalmic laser system (14) according to claim 11, wherein the ophthalmic laser system (14) is designed as an ophthalmic femtosecond laser system for refractive surgical applications is. A method for characterizing a laser beam (12) of an ophthalmic laser system (14), the method comprising:

- Providing a device (10) for characterizing the laser beam (12), which has a contact element (16), collimation optics (18) and a wavefront sensor (20);

- Coupling the device (10) for characterizing the laser beam (12) with the ophthalmic laser system (14) by means of the contact element (16) in such a way that the laser beam (12) emitted by transmission optics (28) of the ophthalmic laser system (14) via the Contact element (16) is coupled into the device (10);

- Collimating the coupled-in laser beam (12) by means of the collimation optics (18);

- Determining a wavefront of the collimated laser beam (12) by means of the wavefront sensor (20). The method of claim 13, further comprising aligning the device (10) relative to the laser system (14) such that a focus point of the collimating optics coincides with the focus (12a) of the laser beam (12). 25 The method of claim 14, further comprising:

- deflecting the laser beam (12) by the ophthalmic laser system (14) such that the focus (12a) of the laser beam (12) is directed to at least one further position in a processing area (1000) of the laser beam (12);

- Displacing the collimating optics (18) and optionally the wavefront sensor (20) relative to the contact element (16) at least in a plane perpendicular to the optical axis (1002) of the collimating optics (18) such that the focus point of the collimating optics (18) with the focus ( 12a) of the laser beam (12) coincides at the at least one further position in the processing area (1000) of the laser beam (12); and

- determining the wave front of the laser beam (12) at the at least one further position in the processing area (1000) of the laser beam (12). The method of claim 15, wherein the laser beam (12) is deflected by a deflector of the ophthalmic laser system (14), and wherein the collimating optics (18) are displaced in response to the deflection of the laser beam (12) by the deflector. Method according to one of Claims 13 to 16, further comprising determining at least one of the following properties of the laser beam (12) using the wavefront of the laser beam (12) determined by the wavefront sensor (20): beam diameter, beam profile, numerical aperture, wavefront error, focus size. Use of a wavefront sensor (20) to characterize the focus (12a) of a laser beam (12) of an ophthalmic laser system (14). Use according to claim 18, wherein the wavefront sensor (20) at an intended position by means of the ophthalmic 26

Laser system (14) can be positioned to be treated and can be coupled to the ophthalmic laser system (14) by means of a contact element (16).