Miniaturized instrument simultaneous vision simulator by generation of masks (Machine-translation by

专利摘要:
Instrument miniaturized simulator of simultaneous vision by generation of masks. A miniaturized simultaneous vision simulator instrument is provided by generating masks with a single optical image-forming channel. The instrument comprises: a mask generating element (egm) that generates, with a frequency of temporary alternation, at least two complementary masks in such a way that when one partially blocks the incident light, the other partially passes the incident light, and vice versa ; an adjustable lens (la) of variable optical power that generates, with said alternating frequency, at least two different optical powers corresponding to at least two observation distances. The egm and the la are located in a single optical channel through which the incident light circulates, so that each mask of the egm is temporarily synchronized with a power of the la. The combination of all the optical masks and powers produces, by temporary fusion at high speed, a pupillary pattern in which at least two optical powers corresponding to at least two observation distances are combined. (Machine-translation by Google Translate, not legally binding)
公开号:ES2610789A1
申请号:ES201531397
申请日:2015-09-30
公开日:2017-05-03
发明作者:Carlos Dorronsoro Diaz；Susana Marcos Celestino
申请人:Consejo Superior de Investigaciones Cientificas CSIC；
IPC主号:

专利说明:

DESCRIPTION

MINIATURIZED INSTRUMENT SIMULTANEOUS VISION SIMULATOR BY MASK GENERATION
 5

SECTOR OF THE TECHNIQUE

The present invention relates, in general, to the field of ocular optics, and in particular to the field of ophthalmic corrections to compensate for presbyopia. 10

STATE OF THE TECHNIQUE

The young human eye has the ability to change its focus to clearly see both distant and near objects. This ability of the eye, called accommodation, is achieved because the lens is able to change its focus, changing the shape of its surfaces. Presbyopia is called loss of accommodation, which happens with age. Presbyopia begins to show symptoms around 45 years of age and makes the entire population from 55 years of age depend on optical corrections of some kind to see correctly from far and near 20. The most common correction of presbyopia is ophthalmic lenses, either in the form of close-up glasses, glasses with bifocal segments or progressive lenses. Despite being the most immediate solution to the problem posed by presbyopia, glasses are far from being considered an optimal solution, for aesthetic reasons or for their discomfort.
Several solutions to alleviate the effects of presbyopia are based on the concept of simultaneous vision. Simultaneous vision corrections superimpose two or more images on the retina, one of which corresponds to a distance of observation of distant vision and another to near vision. The resulting final image on the retina contains a sharp component, in focus, superimposed on another or other unfocused components, out of focus, which results in a general loss of contrast. Not everyone is able to tolerate simultaneous vision. For the adaptation of contact lenses, it is usual for the patient to try different designs. The situation is much worse in the case of surgical solutions since they are irreversible processes. Hence the need to simulate simultaneous vision and provide the patient with the new visual experience before adaptations or surgeries. This is an ideal approach to anticipate and avoid the visual problems that each patient will have, whether optical or neuronal.
In the Spanish patent application with application number P201331436 a new concept for the generation of simultaneous vision, called temporal channel multiplexing, was proposed. It consists in inducing a periodic variation in time in the vergence of the beam of light that passes through it with an adjustable lens. The different levels of vergence, which are repeated periodically, define different temporal channels 5 that are multiplexed temporarily at a frequency greater than the frequency of fusion of the eye, and the spatio-temporal superposition of all the component images forms a final image of simultaneous vision. which is perceived as static.
The invention disclosed in the aforementioned patent application makes use of the concepts of temporal multiplexing to simulate pure simultaneous vision, in which the entire pupil of the eye acts at the same time as a near vision zone and a far vision zone. However, in many real designs of simultaneous vision ophthalmic corrections (contact lenses, infraocular lenses) the pupil is divided into zones, segments, each of which corresponds to a viewing distance (near, intermediate, far). The present invention uses the terms "pupil patterns" to refer to pupils divided into segments or zones of different powers.
The generation of pupillary patterns, with different regions dedicated to distant, near or intermediate vision, spatial light modulators (SLM) can be performed based on cells that produce a variable offset, often accompanied by 20 changes in polarization, in light that affects them, depending on the voltage. The offset at each point is related to the level of each pixel, so that the offset map can be considered as an image, with a spatial resolution determined by the number of pixels. These SLMs can be incorporated into adaptive optics systems (Testing vision with radial and angularly segmented 25 multifocal patterns using adaptive Optics. Maria Vinas, Carlos Dorronsoro, Veronica Gonzalez, Daniel Cortes, Susana Marcos. Investigative Ophthalmology & Visual Science June 2015, Vol. 56, 1358, 2015), operating on the reflection of the light that affects them in what is called reflection mode. Another configuration previously presented (Visual testing of segmented bifocal corrections with a 30 compact simultaneous vision simulator, Carlos Dorronsoro, Aiswaryah Radhakrishnan, Pablo de Gracia, Lucie Sawides, José Ramón Alonso-Sanz, Daniel Cortés, Susana Marcos. Investigative Ophthalmology & Visual Science April 2014, Vol.55, 781, 2014) uses a SLM operating in transmission mode, operating on the light transmission, in combination with a simultaneous two-channel simultaneous vision system 35 (application P200930055), providing pupillary distributions from afar
and close, given by patterns defined in the SLM by binary black and white images.
These simultaneous vision simulation methods are not suitable for compact clinical prototypes because they have great complexity, weight, size and cost.
 Another solution identified is the projection of a phase pattern in the pupil, constructed by microlithography or precision machining.
Other solutions are based on projecting into the eye, by means of optical projection systems, a real intraocular lens (EP 2631891 A1; US 2011/0080562 A1). This approach requires having the different lenses and their variants with different parameters. In addition, it is necessary for the optical system to be sophisticated, to eliminate the optical power of the lens itself, which usually has a value close to 20 diopters. The necessary fastening of the lenses in a cell, for its projection, entails a time of manipulation to physically put and remove the intraocular lens, which makes it possible to make direct and immediate comparisons between different lenses, typical in rigorous experiments of subjective preference . 15 Although they have proven to be a viable approach in laboratory systems, existing systems to simulate pupil patterns are impractical in a robust and portable instrument, for the reasons stated. In addition, in a binocular system, in which the visual simulation is performed in both eyes at the same time, the problem is multiplied. twenty

The technical problem that the present invention solves is the simulation of simultaneous vision in a compact instrument capable of simulating programmable pupil patterns using a single spatial channel. By not resorting to two or more space channels for solving the problem, the associated drawbacks described above are eliminated.

DESCRIPTION OF THE INVENTION

In a first aspect of the invention, a miniaturized instrument simulating simultaneous vision by mask generation is provided. The miniaturized simultaneous vision simulator instrument for mask generation comprises: a mask generating element (EGM) that generates, with a temporal alternating frequency, at least two complementary masks such that, sequentially, each mask partially passes (it is that is to say, for an area of the pupil) an incident light coming from an object, at the same time that the at least one other mask (that is, the rest of the masks) partially blocks (i.e.
other areas of the pupil) the incident light; an adjustable lens of variable optical power that generates, with the frequency of temporal alternation, at least two different optical powers corresponding to at least two observation distances; wherein the mask generating element and the adjustable lens are located in a single optical channel through which the incident light circulates, so that each mask of the mask generating element (EGM) is temporarily synchronized with each lens power adjustable, obtaining a combined pupillary pattern of at least two observation distances by temporal fusion. The combination of all the masks and optical powers produces, by temporary fusion at high speed, a pupillary pattern in which at least two optical powers 10 corresponding to at least two observation distances are combined.
In a particular embodiment, the miniaturized simultaneous vision simulator instrument for mask generation comprises: a mask generating element (EGM) that generates, with a time alternating frequency, two complementary masks such that when, sequentially, one lets pass 15 partially an incident light coming from an object, the other partially blocks the incident light, and vice versa; an adjustable lens of variable optical power that generates, with the frequency of temporal alternation, two different optical powers corresponding to two observation distances; wherein the mask generating element and the adjustable lens are located in a single optical channel through which the incident light circulates, such that each mask of the mask generating element (EGM) is temporarily synchronized with a lens power adjustable, obtaining a pupillary pattern by temporal fusion in which two observation distances are combined.
In another particular embodiment, the simultaneous vision simulator 25 miniaturized instrument for mask generation comprises: a mask generating element (EGM) that generates, with a temporal alternating frequency, at least three complementary masks such that when, sequentially, one partially passes the incident light from an object, the at least two other masks partially block the incident light; an adjustable lens of variable optical power 30 which generates, with the temporal alternation frequency, at least three different optical powers corresponding to at least three observation distances; wherein the mask generating element and the adjustable lens are located in a single optical channel through which the incident light circulates, such that each mask of the mask generating element (EGM) is temporarily synchronized with a lens power adjustable, obtained by fusion
temporal a pupillary pattern in which at least three observation distances are combined.
In the present invention, complementary masks are understood as those masks that are arranged together to cover the entire pupil. In all the examples of embodiment, a mask partially lets the light through (lets light 5 through an area of the pupil) and the rest of the masks partially block the light (through the rest of the pupil's areas) for a certain moment of time. In the next instant of time (equivalent to the inverse of the frequency of the alternation), the mask that let the light pass blocks it, one of the ones that blocked the light lets it pass and the rest of the masks continue to block the light. And so on. Thus 10 is defined “sequentially”.
To produce the visual experience of simultaneous vision without any vibration or flickering of the image, the alternating frequency of the different masks and powers must be higher than the frequency of fusion of the visual system. In one embodiment of the invention, the alternating frequency is preferably greater than 30 Hz, and more preferably greater than 60Hz.
The optical channel contains the incident light from an observed object whose sense of propagation starts from the observed object until it reaches the eye of the observer or patient. Taking into account this sense of light transmission, it is defined for all embodiments of the invention, as the anterior focus of a lens, the focus thereof that is reached by the incident light before passing through the lens and as posterior focus of a lens, the focus of it that is reached by the incident light after passing through the lens.
The image on the retina or retinal image is formed when the light from an object passes through the pupillary pattern and the optics of the eye make it converge on the retina. By the present invention it is achieved that, on an eye of an observer or patient placed in the plane containing the pupil pattern, an image is generated on the retina (retinal image) which is a combination (multiplexing) of several images corresponding to different distances observational. This retinal image is an image of static appearance in the retina, of multifocal character and, therefore, with some degradation. This retinal image simulates the one produced by a real correction since it is equivalent to it, for all intents and purposes.
As mentioned above, for the present invention, the masks let light through some areas and not others. These areas are also called segments. The masks are generated by the 35 Masks Generator Element (EGM). Technologically, the Mask Generating Element (EGM) is achieved by means of a programmable active optical element that can operate
by: i) transmission: a transparent material that allows light to be transmitted through it in some areas and not in others; or, ii) by reflection: a specular material that in some areas reflects but not in others. The EGM in transmission can be achieved by means of a spatial light modulator based on liquid crystal technology, operating in transmission, while the EGM in reflection mode can be achieved by means of a spatial modulator of reflection light or with a Digital micro mirror device. The combination of all masks (EGM) and all powers (LA) by temporal multiplexing produces a pupillary pattern that is projected on the pupil of the patient's eye and that produces the optical effect of a multifocal correction of simultaneous vision: images of retina (10 retinal images) that have overlapping focused and unfocused components. That is, the light, depending on the area of the pupil through which it passes, produces a more or less focused component image in the retina. The superimposition on the retina of the component images, all of the same size, causes each point of the image to be both focused and unfocused, as in real ophthalmic corrections of simultaneous vision.
In another particular embodiment, the simultaneous vision simulator miniaturized instrument for mask generation additionally comprises two projecting lenses, both with the same focal length and two focal distances separated from each other. The instrument configured in such a way that the generating element of 20 masks is in the anterior focus of one of the lenses, and the adjustable lens (LA) is placed approximately in the posterior focus of the other lens, the pupillary pattern forming on the posterior focus of the other lens.
In another particular embodiment, the simultaneous vision simulator miniaturized instrument for mask generation additionally comprises two projecting lenses 25 with the same focal length and two focal distances separated from each other. The instrument configured in such a way that the adjustable lens is in the anterior focus of one of the lenses and the mask generating element is placed approximately in the posterior focus of the other lens, the pupillary pattern forming on the posterior focus of the other lens. 30
In another particular embodiment, the simultaneous vision simulator miniaturized instrument for mask generation additionally comprises two projecting lenses with the same focal length and two focal distances separated from each other. The instrument configured in such a way that the adjustable lens (LA) and the mask generating element (EGM) are in the anterior focus of one of the lenses, 35 and the pupillary pattern is formed on the posterior focal plane of the other lens .
In another particular embodiment, the simultaneous vision simulator miniaturized instrument for mask generation additionally comprises four projecting lenses, two extreme and two intermediate, with the same focal length, consecutively distributed over the optical channel and with a separation between each two lenses consecutive equivalent to two focal distances. The instrument configured in such a way that the mask generating element (EGM) is in the anterior focus of one of the extreme lenses, the adjustable lens (LA) is located in the posterior focus of one of the intermediate lenses that coincides with the anterior focus of the other intermediate lens, and the pupillary pattern is formed on the posterior focus of the other extreme lens. The mask generating element (EGM) can be located non-10 perpendicular to the optical channel, so that the mask generating element (EGM), operating in reflection mode, receives the incident light directly and reflects it in another direction , in which it crosses the four projecting lenses and the adjustable lens (LA).
In another particular embodiment, the simultaneous vision simulator 15 miniaturized instrument for mask generation additionally comprises four projecting lenses, two extreme and two intermediate, with the same focal length, distributed consecutively over the optical channel (CO) and with a separation between every two consecutive lenses equivalent to two focal lengths. The instrument configured in such a way that the adjustable lens (LA) is in the anterior focus of one of the 20 extreme lenses, the mask generating element (EGM) is located in the posterior focus of one of the intermediate lenses that matches the anterior focus of the other intermediate lens, and the pupillary pattern is formed on the posterior focus of the other extreme lens. The mask generating element (EGM) can be located non-perpendicular to the optical channel, such that the mask generating element 25 (EGM), operating in reflection mode, receives the incident light through the adjustable lens ( LA), of an extreme lens and an intermediate lens, and reflects it in another direction, in which it crosses an intermediate lens and an extreme lens.
In another particular embodiment, the simultaneous vision simulator miniaturized instrument for mask generation additionally comprises: four projecting lenses 30, two extreme and two intermediate, with the same focal length, consecutively distributed over the optical channel and with a separation between each two consecutive projecting lenses equivalent to two focal distances; and two extreme mirrors. The instrument is configured in such a way that the incident light passes consecutively by: the adjustable lens (LA), an extreme mirror, an extreme lens 35, an intermediate lens, the mask generating element (EGM) in reflection mode, the another intermediate lens, the other extreme lens and the other mirror, until reaching
the pupillary plane, where you can also find the posterior focus of the other extreme lens.
In another particular embodiment, the simultaneous vision simulator miniaturized instrument for mask generation additionally comprises: four projecting lenses, two extreme and two intermediate, with the same focal length, distributed 5 consecutively over the optical channel and with a separation between each two consecutive projecting lenses equivalent to two focal distances; two extreme mirrors and two intermediate mirrors. The instrument is configured in such a way that the incident light passes consecutively by: the mask generating element (EGM), an extreme mirror, an extreme lens, an intermediate lens, an intermediate mirror 10, the adjustable lens, the other mirror intermediate, the other intermediate lens, the other extreme lens and the other extreme mirror until reaching the pupillary plane, where you can also find the posterior focus of the other extreme lens.
In another particular embodiment, the simultaneous vision simulator miniaturized instrument additionally comprises: four projecting lenses, two extreme and two intermediate lenses, with the same focal length, distributed consecutively over the optical channel and with a separation between each two consecutive projecting lenses equivalent to two focal distances; two extreme mirrors and two intermediate mirrors. The instrument is configured in such a way that the incident light passes consecutively by: the adjustable lens (LA), an extreme mirror, an extreme lens, an intermediate lens, an intermediate mirror, the mask generating element (EGM), the other intermediate mirror, the other intermediate lens, the other extreme lens and the other extreme mirror until reaching the pupillary plane, where the posterior focus of the other extreme lens can also be found.
In another particular embodiment, the simultaneous vision simulator miniaturized instrument 25 additionally comprises: four projecting lenses, two extreme and two intermediate, with the same focal length; two extreme mirrors and two intermediate mirrors; and, a double mirror (two opposite faces). The instrument is configured in such a way that the incident light passes consecutively through a face of the double mirror, the adjustable lens, an extreme lens, an extreme mirror, an intermediate mirror 30, an intermediate lens, the mask generating element (EGM), the other lens, the other intermediate mirror, the other extreme mirror, the other extreme lens and the other side of the double mirror until reaching the pupillary plane, where the posterior focus of the other extreme lens can also be found. The human eye is therefore co-aligned with the incident light. 35
In another particular embodiment, the simultaneous vision simulator miniaturized instrument additionally comprises: four projecting lenses, two extreme and two
intermediate, with the same focal length; two extreme mirrors; and a double mirror (two opposite faces). The instrument is configured in such a way that the incident light passes consecutively through a face of the double mirror, the adjustable lens, an extreme mirror, an extreme lens, an intermediate lens, the mask generating element (EGM), the other intermediate lens, the other extreme mirror, the other extreme lens and the other side of the double mirror until reaching the pupillary plane, where the posterior focus of the other extreme lens can also be found. The human eye is therefore co-aligned with the incident light.
In another particular embodiment, the simultaneous vision simulator miniaturized instrument additionally comprises: four projecting lenses, two extreme and two intermediate, with the same focal length; two extreme mirrors; and a double mirror (two opposite faces). The instrument is configured in such a way that the incident light passes consecutively through the adjustable lens (LA), a double mirror face, an extreme lens, an extreme mirror, an intermediate lens, the mask generating element (EGM), the other intermediate lens, the other extreme mirror, the other extreme lens and the other side of the double mirror, until reaching the pupillary plane, where the posterior focus of the other extreme lens can also be found. The human eye is therefore co-aligned with the incident light.
In a second aspect of the invention, the use of the instrument according to one or more previous embodiments is provided in combination with glasses, contact lenses, intraocular lenses, refractive surgery or other ophthalmic or surgical corrections.
In a third aspect of the invention, the use of the instrument according to one or more previous embodiments as a phoropter is provided.
In a fourth aspect of the invention, the use of the instrument 25 according to one or more previous embodiments in combination with visual or psychophysical tests is provided.
In a fifth aspect of the invention, the use of the instrument according to one or more previous embodiments is provided to assess the tolerance of patients to simultaneous vision corrections or for the training of the patient prior to the implementation of simultaneous vision corrections.

DESCRIPTION OF THE FIGURES

Figure 1A and 1B show two embodiments of the invention to generate the pupillary pattern by multiplexed combination of a mask generating element and an adjustable lens.

Figures 2A and 2B show two embodiments of the present invention with a mask generating element, an adjustable lens and four lenses configured in a rectilinear optical channel for different arrangements of the adjustable lens and the mask generating element. 5

Figures 3A, 3B and 3C show three embodiments of the present invention with a mask generating element, an adjustable lens and two lenses configured in a rectilinear optical channel for different combinations of the adjustable lens and the mask generating element. 10

Figures 4A and 4B show two embodiments of the present invention with a mask generating element, an adjustable lens and four lenses configured in an optical channel that incorporates a reflection on the mask generating element, for different combinations of the lenses, the Adjustable lens and 15 element mask generator.

Figure 5A shows an embodiment of the present invention with a Mask Generator Element, an adjustable lens, four lenses and two mirrors configured in an optical channel in reflection on the 20 Mask Generator Element.

Figures 5B and 5C show two embodiments of the present invention with a Mask Generator Element, an adjustable lens, four lenses and four mirrors configured in an optical channel reflecting on the mirrors for different combinations of the lenses, the adjustable lens , the mirrors and the Mask Generator Element.

Figure 6A shows an embodiment of the present invention with a Mask Generator Element, an adjustable lens, four lenses, a double-sided mirror and four mirrors configured in an optical channel reflecting on the mirrors and the double-sided mirror .

Figures 6B and 6C show two embodiments of the present invention with a Mask Generator Element, an adjustable lens, four lenses and two mirrors 35 configured in an optical channel reflecting on the mirrors and the Mask Generator Element for different combinations of the lenses, the lens
Adjustable, double-sided mirror, mirrors and Mask Generator Element.

EXAMPLE OF EMBODIMENT OF THE INVENTION
 5
Several embodiments of the present invention will be described in more detail below with reference to the accompanying figures, in which preferred embodiments of the invention are shown. However, the invention can be embodied in many different ways and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this exposure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Equal numbers and equal letters refer to equal elements throughout the entire document.
 The present disclosure provides novel solutions for simulation of simultaneous vision applied to presbyopia. Advantageously, the present invention is capable of being implemented in miniaturized devices since it only uses one channel for pupillary image formation. In general, the image on the retina or retinal image is formed when the light coming from an object travels through the optics of the eye that converges on the retina, forming the image of the object on the retina. This retinal image may be focused or out of focus. In the present invention, the light coming from the object forms the retinal image after passing through the pupillary pattern generated by the LA and the EGM, which is projected into the pupil of the eye. By the present invention it is achieved that in the retina of an eye of an observer or patient, the eye is placed in a position such that its pupil coincides with the plane containing the pupil pattern "P" of the instrument, a retinal image is generated which is a combination (multiplexing) of several images corresponding to different observation distances (for example, far vision and near vision).
Figure 1A shows an embodiment of the invention for generating the pupillary pattern 7. Figure 1A shows an adjustable lens LA (of variable focus) that changes its optical power every certain time interval (determined by an alternating frequency) alternating between the power corresponding to far vision F (1) and near vision N (2). The adjustable LA lens is temporarily synchronized with an EGM Mask Generator Element which has, for the embodiment of the invention shown in Figure 1A, two semicircular segments 3a and 3b that complement each other to cover the entire circular beam of light , but in such a way that when a segment blocks the incident light from an observed object (not
shown in the figures), the other segment lets in the incident light, and vice versa. These two combinations of the segments give rise to two different masks (3,5). Therefore, at a given time of time t0, the adjustable lens LA, of variable focus, has a power corresponding to distant vision F, and the EGM provides a semicircular pupillary mask that blocks the left semicircle of the incident light. Through optical projections with a single optical channel, the EGM and LA are made to coincide in a single plane called the pupil plane P because it is the plane in which the pupil of the eye is placed. This projection that combines EGM masks and LA optical power results in the pupil plane P to a transient pupillary pattern 4 that contains an opaque semicircular half (due to the blockage of the segment) 10 and another semicircular half through which It will form a retinal image corresponding to distant vision. At the next instant of time t1, the adjustable lens LA has a power corresponding to near vision N, and the EGM mask generating element provides a semicircular pupillary mask that blocks the right semicircle of the incident light which, through the same optical channel above, 15 crosses the adjustable lens LA and the EGM mask generating element, thus projecting a pupillary pattern 6 (pupillary plane P) containing an opaque semicircular half (by segment blockage) and another semicircular half through which It will form a retinal image corresponding to near vision. In the next instant of time t2 the same configuration of the adjustable lens LA 20 and of the EGM mask generating element that was had for t0 is repeated. In the next instant of time t3 the same setting of the adjustable lens LA and the EGM that was had for t1 is repeated.
This alternate repetition of the time configurations (temporal multiplexing), performed with a frequency higher than the melting threshold of the blink of a person's eye 25, causes a complete pupil pattern 7 to be formed in the pupil of that person (pattern) of segments that cover the entire pupil) which in this example is the combination of two semicircular transient pupillary patterns 4 and 6 corresponding to two different observation distances (near vision and far vision). That is, the complete pupillary pattern is the combination of two transient pupillary patterns. The present invention uses the "alternating frequency" to define the alternating repetition of the configurations. In the configuration shown in Figure 1A there are only two pupillary segments (masks) corresponding to two observation distances, that is, a two-segment bifocal lens is simulated in a semicircle, but the number of configurations can be any other for the expert in the matter. With the same methodology, complete bifocal pupillary patterns can be generated with different angles in the line that separates the
semicircles Bifocal patterns can also be generated in ways other than those shown in the example, for example annular or radial patterns or combination of both. Trifocal patterns can also be generated, which include intermediate vision zones (see figure 1B). In general, pupillary patterns can be generated with any number of foci, with any shape and distribution of the pupillary segments.
Figure 1B shows an embodiment of the invention for generating the pupillary pattern 17. Figure 1B shows an adjustable lens LA (of variable focus) that changes its optical power every certain time interval (determined by an alternating frequency; Δt = 1 / falternance) alternating between the corresponding power 10 at far vision F (8), at intermediate vision I (9) and near vision N (10). The adjustable LA lens is temporarily synchronized with an EGM Mask Generator Element which has, for the embodiment of the invention shown in Figure 1B, three segments 11a (outer and annular), 12a (intermediate and annular) and 13a (central and circular) that complement each other to cover the entire circular beam of light, but in such a way that when one segment lets in the incident light, the other two segments block the incident light from an observed object (not shown in the figures) ) thus forming a different mask for each combination of the segments (11, 12, 13). Therefore, at time t0, the adjustable lens LA, of variable focus, has a power corresponding to distant vision F, and the EGM 20 provides an annular pupil mask that lets light through the outer segment 11a, so cancel. For this, the outer segment 11a lets in the light and the intermediate segments 12a and central 13a block the incident light. The intermediate and central segments 12a 13a when they block the light together are referred to as a single segment 11b for t = t0. By means of optical projections with a single optical channel, the EGM and LA are made to coincide in a single plane, which we call pupil plane P because it is the plane in which the pupil of the eye is placed. This projection that combines EGM masks and LA optical power results in the pupil plane P to a transient pupillary pattern 14 that contains a circular zone that blocks light by 40%, and an annular zone that lets light through 60%, through which a retinal image corresponding to distant vision will be formed. At the next instant of time t1, the adjustable lens LA has a power corresponding to intermediate vision I (9), and the EGM mask generating element provides an intermediate annular pupil mask where the intermediate segment 12a lets the light in at 30% while the central and outer segments 13a 11a (the 35 segments 13a and 11a are jointly referred to as 12b at t = t1) block 70% of the incident light that, through the same previous optical channel, crosses the lens
adjustable LA and the EGM mask generating element, thus projecting a pupillary pattern 15 (pupillary plane P) containing two opaque zones corresponding to the outer and central segments, and an intermediate annular zone through which a corresponding retinal image will be formed at intermediate vision. At the next instant of time t2, the adjustable lens LA has a power corresponding to near vision N (10), and the EGM mask generating element provides a pupil mask that only lets 10% of the incident light pass. The circular incident light through the same anterior optical channel passes through the adjustable lens LA and the EGM mask generating element, thus projecting a pupillary pattern 16 (pupillary plane P) containing an opaque annular area occupying 90% (by blocking of segments 10 11a, 12a, jointly referenced as 13b at t = t2) and a circular zone that occupies 10% through which a retinal image corresponding to near vision will be formed. In the next moment of time t3 the same configuration of the adjustable lens LA and the mask generating element EGM that was had for t0 is repeated. In the next instant of time t4 the same configuration of the adjustable lens 15 LA and the EGM that was had for t1 is repeated. And so on.
As for the optical system that provides the configuration described in Figure 1A and / or 1B of the adjustable LA lens and the EGM mask generating element, there are different configurations or embodiments according to the needs of the miniaturized simultaneous vision simulator instrument. Some of the possible configurations or embodiments are described below.
The simultaneous vision simulator instrument is miniaturized as a result of the configuration in a single optical channel that can be rectilinear or non-rectilinear. In the latter case, the incorporation of mirrors in the instrument makes it possible to fold the optical path, which contributes to the miniaturization of the instrument.
The embodiments described below use different optical projection methods based on projections with pairs of lenses, considering their properties and limitations. Thus, in a projection system with two lenses with equal focal distances and two focal distances separated from each other, an object or an optical element placed in the anterior focus of one of the lenses is projected in the posterior focus of the other lens, where another optical element may be placed in the eye of a user. In this configuration the image is inverted. To solve this, two additional lenses that make up another projection system that cancel the previous inversion can be added to the instrument, as shown in Figures 2A and 2B. 35 But introducing additional lenses implies that the instrument requires more
length that must be added to the natural reading distance, and therefore is severely altered.
Figure 2A shows an exemplary embodiment of the present invention where the miniaturized instrument simulating simultaneous vision by mask generation has an EGM Mask Generator Element, an adjustable LA lens, with a variable focal length, and four projecting lenses L1, L2, L3 and L4 configured in a single rectilinear CO optical channel. In the implementation shown in Figure 2A, the incident light from the observed object (not shown in the figure), which travels through the optical channel in the direction shown in Figure 2A, consecutively crosses the EGM, the extreme lens L1, the intermediate lens L2, the adjustable lens LA, 10 the intermediate lens L3 and finally the extreme lens L4 until reaching the pupillary plane P where the complete pupillary pattern is projected as described in the embodiment example of Fig. 1A - 1 B. L1, L2, L3 and L4 lenses have the same focal length. The separation between each two consecutive projecting lenses equivalent to two focal lengths, such that the EGM mask generating element is found in the anterior focal plane FL1 of the end lens L1. The adjustable LA lens is located at the rear focus FL2 of the L2 lens that matches the previous focus FL3 of the L3 lens. Finally, the pupillary pattern P projects on the posterior focal plane FL4 of the other end lens L4.
Figure 2B shows an exemplary embodiment of the present invention where the miniaturized simultaneous vision simulator instrument for mask generation has an EGM Mask Generator Element, an adjustable LA lens, variable focal lens, and four projecting lenses L1, L2, L3 and L4 configured in a single rectilinear CO optical channel. In the implementation shown in Figure 2B, the incident light from the observed object, which travels through the optical channel according to the direction shown in Figure 2B, consecutively crosses the adjustable lens LA, the end lens L1, the lens intermediate L2, the mask generating element EGM, the intermediate lens L3 and finally the extreme lens L4 until reaching the pupillary plane P where the complete pupil pattern is projected as described in the embodiment example of Figure 1 A-1B. The four projecting lenses L1, L2, L3 and L4 have 30 the same focal length. The separation between every two consecutive lenses equivalent to two focal lengths, such that the adjustable lens LA is in the anterior focus FL1 of the extreme lens L1, the mask generating element EGM is located in the posterior focus FL2 of the lens intermediate FL2 that matches the previous focus FL3 of the intermediate lens L3. Finally, pupillary pattern 35 is projected onto the posterior focal plane FL4 of the other end lens L4.
When the user uses the instrument described in Figures 2A or 2B to observe a nearby object, the reading distance is greatly altered due to the length of the instrument and the use of four projecting lenses. So that the reading distance has a smaller affectation, different implementations based on the use of only two projection lenses can be used. Three of these configurations 5 are shown in Figures 3A, 3B and 3C. In Fig. 3A an EGM is placed in transmission mode in the anterior focus of a projection lens, and the adjustable lens LA is placed in a plane as close as possible to the pupillary plane P, in the posterior focus of the other lens ( in P the pupil of the eye is located, and therefore the LA may be close to, but not exactly above, the pupillary plane P). In Fig. 3B, the same solution as in Fig. 10 3A, but exchanging the EGM for the adjustable lens. In Fig. 3C, the two EGM and LA elements are positioned, approximately, in the anterior focus of the first projection lens.
Figure 3A shows an example of embodiment of the present invention where the miniaturized instrument simulating simultaneous vision by generation of 15 masks has an EGM mask generating element, an adjustable LA lens, variable focal lens, and two projecting lenses L1 and L2, configured in a single rectilinear CO optical channel. In the implementation shown in Figure 3A, the incident light from the observed object (not shown in the figure), which travels through the optical channel CO in the direction shown in Figure 3A, consecutively passes through the generating element 20 EGM masks, the lens L1, the lens L2 and the adjustable lens LA, until reaching the pupillary plane P where the complete pupil pattern is projected as described in the embodiment example of Figure 1A-1B. L1 and L2 lenses have the same focal length. The separation between the lenses L1 and L2 equivalent to two focal distances, such that the EGM mask generating element is in the anterior focus FL1 of the lens L1, the entire pupil pattern is formed on the pupil plane P which coincides with the posterior focal plane of lens L2, and the adjustable lens LA is approximately in the posterior focus FL2 of the lens L2.
Figure 3B shows an exemplary embodiment of the present invention where the miniaturized instrument simulating simultaneous vision by generation of 30 masks has an EGM mask generating element, an adjustable lens LA of variable focus, and two projecting lenses L1 and L2, configured in a single rectilinear CO optical channel. In the implementation shown in Figure 3B, the incident light from the observed object (not shown in the figure) and traveling in the direction shown in Figure 3B through the optical channel CO, consecutively passes through the adjustable lens LA , the projecting lens L1, the projecting lens L2 and the EGM mask generating element, until reaching the pupillary plane P where the
complete pupillary pattern as described in the embodiment example of figure 1. The projecting lenses L1 and L2 have the same focal length. The separation between the lenses L1 and L2 equivalent to two focal distances, such that the adjustable lens LA is in the anterior focus FL1 of the lens L1, the entire pupil pattern is formed on the pupil plane P is projected onto the plane focal lens 5 of lens L2, and the mask generating element EGM is approximately in the posterior focus FL2 of lens L2.
Figure 3C shows an exemplary embodiment of the present invention where the miniaturized instrument simulating simultaneous vision by mask generation has an EGM mask generating element, an adjustable lens LA of 10 focal variable, and two projecting lenses L1 and L2, configured in a single rectilinear CO optical channel. In the implementation shown in Figure 3C, the incident light coming from the object observed (not shown in the figure) and traveling in the direction shown in Figure 3C through the optical channel CO, consecutively crosses the mask generating element EGM, the adjustable lens LA, the projecting lens L1 15 and the projecting lens L2, until reaching the pupillary plane P where the complete pupil pattern is projected as described in the embodiment example of Figure 1A-1B. The L1 and L2 projecting lenses have the same focal length. The separation between lenses L1 and L2 equivalent to two focal distances. The mask generating element EGM and the adjustable lens LA are approximately in the anterior focus 20 of the lens L1. The complete pupillary pattern P is projected onto the posterior focal plane of the lens L2. LA and EGM can exchange their positions, providing a similar configuration.
By using only two projection lenses in the examples of Figures 3A, 3B and 3C the projection and superposition of elements is not as accurate as in the 25 examples of Figures 2A and 2B, but it can be a sufficiently good approximation. In addition, with the use of only two projection lenses in the examples of Figures 2A, 2B and 2C, an inversion is made in the image that can be compensated by introducing rectifying mirrors or prisms into the system (something not shown in the figures). ). 30
In the exemplary embodiments shown in Figures 2A, 2B, 3A, 3B and 3C, the optical channel is rectilinear and all the elements (EGM, LA, projecting lenses) placed on the optical channel are placed on a straight line that passes through P , the plane in which the pupil of the user's eye is located. Also, the EGM mask generating element in the embodiments shown in Figures 2A, 2B, 3A, 3B and 3C 35 operates in transmission mode. Other embodiments of the invention are described below where the optical channel undergoes different reflections for
optimize space and, therefore, the design of the miniaturized instrument of the present invention. Some of these reflections are produced by an EGM operating in reflection mode.
Figure 4A shows an example of embodiment of the present invention where the miniaturized instrument simulating simultaneous vision by generation of 5 masks has an EGM Mask Generating Element, an adjustable lens LA, two extreme lenses L1 and L4 and two intermediate lenses L2 and L3 configured in a single CO optical channel. The EGM Mask Generator Element works in reflection mode in the present embodiment, which determines the arrangement of other instrument elements. In the implementation shown in Figure 4A, the incident light, which travels through the optical channel CO in the direction shown in Figure 4A, has a non-perpendicular impact on the EGM mask generating element, which reflects the incident light for consecutively passing through the extreme lens L1, the intermediate lens L2, the adjustable lens LA, the intermediate lens L3 and finally the extreme lens L4 until reaching the pupillary plane P where the complete pupillary pattern 15 is projected as described in the exemplary embodiment of Figure 1A-1B. All projecting lenses L1, L2, L3 and L4 have the same focal length. The separation between each two consecutive projecting lenses equivalent to two focal distances, such that the EGM mask generating element is in the anterior focus FL1 of the extreme lens L1, the adjustable lens LA is in the posterior focus 20 FL2 of the intermediate lens L2 that coincides with the previous focus FL3 of the intermediate lens L3. The complete pupillary pattern is formed on the posterior focal plane FL4 of the extreme lens L4 which coincides with the pupillary plane P.
Figure 4B shows an example of embodiment of the present invention where the miniaturized instrument simulating simultaneous vision by generation of 25 masks has an EGM Mask Generator Element operating in reflection mode, an adjustable lens LA of variable focus, two extreme lenses L1 and L4 and two intermediate lenses L2 and L3 configured in a single CO optical channel. In the implementation shown in Figure 4B, the incident light, which travels through the optical channel in the direction shown in Figure 4B, consecutively crosses the adjustable lens 30, the extreme lens L1, the intermediate lens L2, after which it affects non-perpendicularly on the EGM mask generating element, which reflects the incident light so that the intermediate lens L3 and the extreme lens L4 are consecutively crossed to finally reach the pupillary plane P where the complete pupillary pattern is projected as it has been described in the exemplary embodiment of Figure 1A-35 1B. The projecting lenses L1, L2, L3 and L4 have the same focal length. The separation between every two consecutive projecting lenses, along the way
optical, is equivalent to two focal distances. The adjustable lens LA is located in the anterior focus FL1 of the extreme lens L1 and the mask generating element EGM is located in the posterior focus of the intermediate lens FL2 which coincides with the anterior focus FL3 of the intermediate lens L3. The complete pupillary pattern P is formed on the focal plane located on the posterior focus FL4 of the extreme lens L4. 5
The element generating masks in reflection mode is what imposes an optical channel with at least one reflection. The optical channel with reflections can be used to make the system more compact. That is why, the embodiments shown in Figures 5A, 5B and 5C are more compact with respect to the embodiments shown in Fig. 2, the line of sight is not altered as in Figs. 4 and 10 improve the performance with respect to Fig. 3. The alteration of the reading distance is smaller in this exemplary embodiment, thanks to the various reflections in the optical path. In addition, unlike the examples in Figure 4, the optical channel is aligned between the input and the output of the instrument, whereby there is no involvement of the eye's line of sight. In the exemplary embodiment of Figure 5A, the miniaturized instrument simulating simultaneous vision by mask generation has an EGM Mask Generator Element, an adjustable LA lens, two extreme lenses L1 and L4, two intermediate lenses L2 and L3 and two E1 and E2 mirrors configured in a single CO optical channel. In the implementation shown in Figure 5A, the incident light coming from the observed object (not shown in the figure), which travels through the optical channel in the direction shown in Figure 5A, passes through the adjustable lens LA, incides in a way non-perpendicular on the mirror E1 where it is reflected to consecutively pass through the extreme lens L1 and the intermediate lens L2, after which it impacts non-perpendicularly on the mask generating element EGM (in reflection mode), which reflects the light incident so that the intermediate lens L3 and the end lens L4 are consecutively crossed to finally be reflected by the mirror E2 until reaching the pupillary plane P where the complete pupillary pattern is projected as described in the embodiment example of the figure 1A - 1B. All projecting lenses L1, L2, L3 and L4 have the same focal length. The separation between every two consecutive projecting lenses, along the optical path, is equivalent to two focal lengths. The E1 mirror can be found at any point in the optical channel between the LA adjustable lens and the L1 extreme lens. The adjustable lens LA is located at the anterior focus FL1 of the extreme lens L1 and at a distance thereof equivalent to a focal length. The mask generating element EGM is located at the rear focus FL2 of the intermediate lens L2 which coincides with the previous focus 35 FL3 of the other intermediate lens L3. The E2 mirror can be found anywhere between the extreme lens L4 and the pupillary plane P.
Figure 5B shows a more compact embodiment of the present invention with respect to the embodiments shown in Figures 2A, 2B, 4A and 4B. The miniaturized simultaneous vision simulator instrument for mask generation has an EGM Mask Generator Element (in transmission mode), an adjustable LA lens with variable focus, two extreme lenses L1 and L4, two intermediate lenses 5 L2 and L3, two extreme mirrors E1 and E2 and two intermediate mirrors E3 and E4 configured in a single optical channel CO. In the implementation shown in Figure 5B, the incident light from the observed object (not shown in the figure), which travels through the optical channel in the direction shown in Figure 5B, crosses the EGM mask generating element, affects non-perpendicular shape on the mirror E1 where it is reflected to consecutively pass through the extreme lens L1 and the intermediate lens L2, after which it impacts non-perpendicularly on the intermediate mirror E3 to pass through the adjustable lens LA and reach the other mirror intermediate E4, which reflects the incident light so that the intermediate lens L3 and the extreme lens L4 pass through consecutively to finally be reflected by the mirror E2 15 until reaching the pupillary plane P where the complete pupillary pattern is projected as described in the exemplary embodiment of Figure 1A-1B. All projecting lenses L1, L2, L3 and L4 have the same focal length. The separation between every two consecutive projecting lenses, along the optical path, is equivalent to two focal distances. The mirror E1 can be found at any point of the optical camium 20 between the end lens L1 and the mask generating element. The EGM mask generating element is at a distance equivalent to a focal length of the extreme lens L1, along the optical path. The E3 mirror can be found at any point of the optical path between the intermediate lens L2 and the adjustable lens LA. In turn, the mirror E4 can be found at any point of the optical path 25 between the adjustable lens LA and the other intermediate lens L3. The adjustable lens LA is located between both intermediate mirrors E3 and E4 at a focal distance, along the optical path, of the intermediate lenses L2 and L3. The mirror E2 can be found at any point in the optical path between the extreme lens L4 and the pupillary plane P where the entire pupil pattern is projected. 30
Figure 5C shows a more compact embodiment of the present invention with respect to the embodiments shown in Figures 2A, 2B, 3A, 3B, 3C, 4A and 4B. The miniaturized simultaneous vision simulator instrument for mask generation has an EGM Mask Generator Element (operating in transmission mode), an adjustable LA lens with variable focus, two extreme lenses 35 L1 and L4, two intermediate lenses L2 and L3, two mirrors ends E1 and E2, and two intermediate mirrors E3 and E4 configured in a single optical channel CO. In the
implementation shown in Figure 5C, the incident light coming from the observed object (not shown in the figure), which travels through the optical channel in the direction shown in Figure 5C, crosses the adjustable lens LA, affects non-perpendicularly on the mirror E1 where it is reflected to consecutively pass through the extreme lens L1 and the intermediate lens L2, after which it impacts perpendicularly no-5 on the intermediate mirror E3 to pass through the mask generating element EGM and reach the other intermediate mirror E4 , which reflects the incident light so that the intermediate lens L3 and the extreme lens L4 will pass consecutively to finally be reflected by the mirror E2 until reaching the pupillary plane P where the complete pupillary pattern is projected as described in the example of 10 embodiment of Figure 1A-1B. All projecting lenses L1, L2, L3 and L4 have the same focal length. The separation between every two consecutive projecting lenses, along the optical path, is equivalent to two focal distances. The mirror E1 can be placed anywhere in the optical channel CO between the adjustable lens and the extreme lens L1. The adjustable LA lens is at a distance from the extreme lens L1 15 equivalent to a focal length. The mirror E3 can be located at any point of the optical channel between the intermediate lens L2 and the mask generating element EGM. The E4 mirror can be located at any point of the optical channel between the EGM Mask Generator Element and the other intermediate lens L3. The EGM mask generating element is located between both intermediate mirrors E3 and E4 at a focal length, along the optical path, of the intermediate lenses L2 and L3. The end mirror E2 can be located at any point of the optical path between the end lens L4 and the pupillary plane P where the entire pupil pattern is projected.
Figure 6A shows the most compact embodiment of the present invention of those described so far with four projecting lenses. The 25 miniaturized simultaneous vision simulator instrument for mask generation has an EGM Mask Generator Element, an adjustable LA variable focus lens, a double mirror (double sided) MM, two extreme lenses L1 and L4, two intermediate lenses L2 and L3 , two extreme mirrors E1 and E2, and two intermediate mirrors E3 and E4 configured in a single optical channel CO. The inclusion of the double-sided mirror 30 MM at 45 degrees with respect to the incident light and also with respect to the line of sight of the eye allows the optical channel CO to suffer a deviation that allows it to pass through the elements included in the embodiment shown in Figure 6A, traveling a long optical path to return, co-aligned, to the starting point. Therefore, the affectation of the reading distance is minimal. In the implementation 35 shown in Figure 6A, the incident light that travels through the optical channel CO in the direction shown in Figure 6A is reflected on a face of the double-sided mirror MM,
it crosses the adjustable lens LA, the extreme lens L1 and impacts non-perpendicularly on the end mirror E1 where it is reflected to be again reflected by the intermediate mirror E3, after which the intermediate lens L2, the mask generating element consecutively passes through EGM, the intermediate lens L3 until reaching the intermediate mirror E4 where it is reflected until reaching the extreme mirror E2, where it is 5 again reflected to cross the extreme lens L4, reach the other side of the double-sided mirror MM where the light is again reflected until reaching the pupillary plane P where the complete pupillary pattern is projected as described in the embodiment example of Figure 1A-1B. All lenses have the same focal length projection except for the LA adjustable lens. All projecting lenses L1, L2, 10 L3 and L4 have the same focal length. The separation between every two consecutive projecting lenses, along the optical path, is equivalent to two focal distances. The adjustable LA lens is at a focal distance from the extreme lens L1. The end mirror E1 and the intermediate mirror E3 can be found at any point in the optical channel between the extreme lens L1 and the intermediate lens L2 while maintaining the condition that the distance between the extreme lens L1 and the intermediate lens L2 along the Optical path is two focal distances. The EGM mask generating element is equidistant (at a focal distance) from the intermediate lenses L2 and L3. The intermediate mirror E4 and the end mirror E2 can be found at any point in the optical channel between the intermediate lens L3 and the extreme lens 20 L4 while maintaining the condition that the distance between the intermediate lens L3 and the extreme lens L4, along the Optical path is two focal distances. The complete pupillary pattern is projected onto the pupillary plane P located at a focal distance from the extreme lens L4 along the optical path.
Figure 6B shows a more compact embodiment of the present invention with respect to the embodiments shown in Figures 2A, 2B, 4A, 4B, 5A, 5B and 5C. The miniaturized simultaneous vision simulator instrument for mask generation has an EGM Mask Generator Element (in reflection mode), an adjustable LA lens with variable focus, a double mirror (double side) MM, two extreme lenses L1 and L4, two lenses intermediate L2 and L3, and two mirrors E1 and E2. 30 All the above elements are configured in a single optical channel CO. The inclusion of the double-sided mirror MM at 45 degrees with respect to the incident light and also with respect to the line of sight of the eye allows the optical channel CO to suffer a deviation that allows it to pass through the elements included in the example of embodiment shown in the Figure 6A, traveling a long optical path to return, co-aligned, to the starting point. Therefore, in the implementation shown in Figure 6B, the incident light from the observed object (not shown in the figure), which
it travels through the optical channel in the direction shown in Figure 6B, crosses the adjustable lens LA, is reflected on a face of the double-sided mirror MM, crosses the extreme lens L1 and impacts non-perpendicularly on the mirror E1 where It is then reflected through the intermediate lens L2 and reach the EGM mask generating element, operating in reflection mode. The generating element of 5 EGM masks reflects the incident light and orients it towards the intermediate lens L3. After passing through the intermediate lens L3 it reaches the mirror E2 where it is reflected to pass through the extreme lens L4. Finally, the light reaches the other side of the double-sided mirror MM where it is again reflected until reaching the pupillary plane P where the complete pupillary pattern is projected as described in the example of embodiment of Figure 1A-1B. All projecting lenses L1, L2, L3 and L4 have the same focal length. The separation between every two consecutive projecting lenses, along the optical path, is equivalent to two focal distances. The adjustable lens LA is in the focal plane of the extreme lens L1, considering the reflection in the double-sided mirror MM, which is physically positioned obliquely, and about 45 to 15 degrees, between the adjustable lens LA and the extreme lens L1. At the same time, on its rear face, MM is positioned obliquely between the extreme lens L4 and the pupillary plane P (where the pupil of the subject's eye is located), such that the pupillary plane P is in the posterior focal plane of the extreme lens L4 because both, the extreme lens L4 and the pupillary plane P, are one focal length away along the optical path. The mirror 20 E1 can be found at any point in the optical channel between the extreme lens L1 and the intermediate lens L2. Similarly, the mirror E2 can be found at any point in the optical channel between the intermediate lens L3 and the extreme lens L4. The EGM mask generating element is located at the rear focus FL2 of the intermediate lens L2 which coincides with the previous focus FL3 of the other intermediate lens L3. The complete pupillary pattern is projected onto the pupillary plane P located at a focal distance from the other end lens L4.
Figure 6C shows a more compact embodiment of the present invention with respect to the embodiments shown in Figures 2A, 2B, 4A, 4B, 5A, 5B and 5C. The miniaturized simultaneous vision simulator instrument for 30 mask generation has an EGM Mask Generator Element, an adjustable LA lens with variable focal length, a double mirror (double sided) MM, two extreme lenses L1 and L4, two intermediate lenses L2 and L3 , two mirrors E1 and E2, configured in a single optical channel CO. The inclusion of the double-sided mirror MM at 45 degrees with respect to the incident light and also with respect to the line of sight of the eye allows the optical channel CO to suffer a deviation that allows it to pass through the elements included in the embodiment shown in Figure 6A, running a
Long optical path to return, co-aligned, to the starting point. Therefore, in the implementation shown in Figure 6C, the incident light from the observed object (not shown in the figure), which travels through the optical channel in the direction shown in Figure 6C, is reflected on a mirror face double MM, crosses the adjustable lens LA, is reflected in the mirror E1, consecutively passes through the extreme lens 5 L1 and the intermediate lens L2 and strikes non-perpendicularly on the EGM mask generating element operating in reflection mode where it is reflected for then cross the intermediate lens L3 and be reflected by the mirror E2. The mirror E2 reflects the light and directs it towards the extreme lens L4 that crosses it until it reaches the other side of the double-sided mirror MM where it is again reflected until reaching the pupillary plane P (the pupil of the user) where the pattern is formed Complete pupil as described in the exemplary embodiment of Figure 1A-1B. All lenses have the same focal length projection except for the LA adjustable lens. All projecting lenses L1, L2, L3 and L4 have the same focal length. The separation between every two consecutive projecting lenses, along the optical path, is equivalent to two focal distances. The complete pupillary pattern is formed on the pupillary plane P located at a focal distance, along the optical path, of the extreme lens L4.
 To implement the EGM mask generator element, a "Digital Micromirror Device" (DMD) or a "Spatial Light Modulator" (SLM) can be used for any previous embodiments. Spatial Light Modulator can work in reflection mode or in transmission mode. In contrast, the "Digital Micromirror Device" (DMD) works only in reflection.

权利要求:
Claims (20)
[1]


1.- Simultaneous miniaturized instrument simulator of vision by generation of 5 masks, characterized by comprising:
 a mask generating element (EGM) that generates, with a frequency of temporal alternation, at least two complementary masks (3, 5) such that, sequentially, each mask partially lets an incident light from an object pass, to while the at least one other mask 10 partially blocks said incident light;
 an adjustable lens (LA) of variable optical power that generates, with said time alternating frequency, at least two different optical powers (1, 2) corresponding to at least two observation distances;
wherein the mask generating element and the adjustable lens are located in a single optical channel (CO) through which said incident light circulates, such that each mask (3) of the mask generating element is temporarily synchronized with each power (4) of the adjustable lens, a combined pupillary pattern (7) of at least two observation distances being obtained by temporary fusion.
 twenty
[2]
2. Simultaneous miniaturized instrument simulating vision by generation of masks according to claim 1, characterized in that the alternating frequency is preferably greater than 30 Hz, and more preferably greater than 60Hz.

[3]
3. Simultaneous miniaturized instrument simulating vision by generation of 25 masks according to claim 1, characterized in that it additionally comprises two projecting lenses (L1, L2), both with the same focal length and two focal distances separated from each other; such that the mask generating element (EGM) is in the anterior focus of one of the lenses (L1), and the adjustable lens (LA) is placed approximately in the posterior focus of the other lens (L2), forming the pupillary pattern on the posterior focus of said other lens (L2).

[4]
4. Simultaneous miniaturized instrument simulating vision by generation of masks according to claim 1, characterized in that it additionally comprises two projecting lenses (L1, L2) with the same focal length and separated from each other two focal lengths; such that the adjustable lens (LA) is in the anterior focus of one of the lenses (L1) and the mask generating element (EGM) is
approximately placed in the posterior focus of the other lens (L2), the pupillary pattern forming on the posterior focus of said other lens (L2).

[5]
5. Simultaneous miniaturized instrument simulating vision by generation of masks according to claim 1, characterized in that it additionally comprises two projecting lenses (L1, L2) with the same focal length and two focal distances separated from each other; such that the adjustable lens (LA) and the mask generating element (EGM) are in the anterior focus of one of the lenses (L1), and the pupillary pattern is formed on the posterior focal plane of said other lens ( L2).
 10
[6]
6. Miniaturized simultaneous vision simulator instrument for mask generation according to claim 1, characterized in that it additionally comprises four projecting lenses (L1, L2, L3, L4), two extremes (L1, L4) and two intermediates (L2, L3 ), with the same focal length, distributed consecutively over said optical channel (CO) and with a separation between every two consecutive lenses 15 equivalent to two focal distances, such that the mask generating element (EGM) is in the anterior focus (FL1) of one of the extreme lenses (L1), the adjustable lens LA is located in the posterior focus (FL2) of one of the intermediate lenses that coincides with the anterior focus (FL3) of the other intermediate lens, and the pupillary pattern is formed on the posterior focus (FL4) of the other extreme lens 20 (L4).

[7]
7. Miniaturized instrument simulating simultaneous vision by generation of masks according to claim 1, characterized in that it additionally comprises four projecting lenses (L1, L2, L3, L4), two extremes (L1, L4) and two intermediate 25 (L2, L3), with the same focal length, distributed consecutively over said optical channel (CO) and with a separation between every two consecutive lenses equivalent to two focal lengths, such that the adjustable lens (LA) is in the focus anterior (FL1) of one of the extreme lenses (L1), the mask generating element (EGM) is located in the posterior focus (FL2) of one of the 30 intermediate lenses that coincides with the anterior focus (FL3) of the other intermediate lens, and the pupillary pattern is formed on the posterior focus (FL4) of the other extreme lens (L4).

[8]
8. Miniaturized simultaneous vision simulator instrument for mask generation according to claim 6, characterized in that the 35 mask generating element (EGM) is located non-perpendicular to the optical channel, such that the mask generating element (EGM), operating in reflection mode, receives
directly the incident light and reflects it in another direction, in which it crosses the four projecting lenses (L1, L2, L3, L4) and the adjustable lens (LA).

[9]
9. Simultaneous miniaturized instrument simulating vision by generation of masks according to claim 7, characterized in that the 5 mask generating element (EGM) is located non-perpendicular to the optical channel, such that the mask generating element (EGM), operating in reflection mode, receives the incident light through the adjustable lens (LA), an extreme lens (L1) and an intermediate lens (L2), and reflects it in another direction, in which it passes an intermediate lens (L3) and an extreme lens (L4). 10

[10]
10. Simultaneous miniaturized instrument simulating vision by generation of masks according to claim 1, characterized in that it additionally comprises: four projecting lenses (L1, L2, L3, L4), two extremes (L1, L4) and two intermediate (L2, L3), with the same focal length, distributed consecutively over said optical channel (CO) and with a separation between each two consecutive projecting lenses equivalent to two focal distances; and two extreme mirrors (E1, E2); where the instrument is configured in such a way that the incident light passes consecutively by: the adjustable lens (LA), an extreme mirror (E1), an extreme lens (L1), an intermediate lens (L2), the generating element of masks (EGM) in 20 reflection mode, the other intermediate lens (L3), the other extreme lens (L4) and the other mirror (E2), until reaching the pupillary plane (P).

[11]
11. Miniaturized simultaneous vision simulator instrument for mask generation according to claim 1, characterized in that it additionally comprises: four projecting lenses (L1, L2, L3, L4), two extremes (L1, L4) and two intermediates (L2 , L3), with the same focal length, distributed consecutively over said optical channel (CO) and with a separation between each two consecutive projecting lenses equivalent to two focal distances; two extreme mirrors (E1, E2) and two intermediate mirrors (E3, E4); where the instrument is configured in such a way that the incident light passes consecutively by: the mask generating element (EGM), an extreme mirror (E1), an extreme lens (L1), an intermediate lens (L2), a intermediate mirror (E3), the adjustable lens (LA), the other intermediate mirror (E4), the other intermediate lens (L3), the other extreme lens (L4) and the other extreme mirror (E2) until reaching the pupillary plane ( P). 35

[12]
12. Miniaturized simultaneous vision simulator instrument for mask generation according to claim 1, characterized in that it additionally comprises: four projecting lenses (L1, L2, L3, L4), two extremes (L1, L4) and two intermediates (L2, L3), with the same focal length, distributed consecutively over said optical channel (CO) and with a separation between each two consecutive projecting lenses 5 equivalent to two focal distances; two extreme mirrors (E1, E2) and two intermediate mirrors (E3, E4); where the instrument is configured in such a way that the incident light passes consecutively by: the adjustable lens (LA), an extreme mirror (E1), an extreme lens (L1), an intermediate lens (L2), an intermediate mirror ( E3), the mask generating element (EGM), the other intermediate mirror 10 (E4), the other intermediate lens (L3), the other extreme lens (L4) and the other extreme mirror (E2) until reaching the pupillary plane ( P).

[13]
13. Miniaturized simultaneous vision simulator instrument for mask generation according to claim 1, characterized in that it additionally comprises: four projecting lenses (L1, L2, L3, L4), two extremes (L1, L4) and two intermediates (L2 , L3), with the same focal length; two extreme mirrors (E1, E2) and two intermediate mirrors (E3, E4); and, a double mirror (MM); where the instrument is configured in such a way that the incident light passes consecutively through a face of the double mirror (MM), the adjustable lens (LA), an extreme lens (L1), an extreme mirror 20 (E1), an intermediate mirror ( E3), an intermediate lens (L2), the mask generating element (EGM), the other intermediate lens (L3), the other intermediate mirror (E4), the other extreme mirror (E2), the other extreme lens (L4) and the other side of the double mirror (MM) until reaching the pupillary plane (P).
 25
[14]
14. Miniaturized instrument simulating simultaneous vision by generation of masks according to claim 1, characterized in that it additionally comprises: four projecting lenses (L1, L2, L3, L4), two extremes (L1, L4) and two intermediate (L2, L3), with the same focal length; two extreme mirrors (E1, E2); and a double mirror (MM); where the instrument is configured in such a way that the incident light 30 passes consecutively through a face of the double mirror (MM), the adjustable lens (LA), an extreme mirror (E1), an extreme lens (L1), an intermediate lens ( L2), the mask generating element (EGM), the other intermediate lens (L3), the other extreme mirror (E2), the other extreme lens (L4) and the other side of the double mirror (MM) until reaching the pupillary plane (P). 35

[15]
15. Miniaturized instrument simulating simultaneous vision by generation of masks according to claim 1, characterized in that it additionally comprises: four projecting lenses (L1, L2, L3, L4), two extremes (L1, L4) and two intermediate (L2, L3), with the same focal length; two extreme mirrors (E1, E2); and a double mirror (MM); where the instrument is configured such that the incident light 5 runs consecutively through the adjustable lens (LA), a double mirror face (MM), an extreme lens (L1), an extreme mirror (E1), an intermediate lens ( L2), the mask generating element (EGM), the other intermediate lens (L3), the other extreme mirror (E2), the other extreme lens (L4) and the other side of the double mirror (MM), until the plane is reached pupillary (P). 10

[16]
16. Use of the instrument according to previous claims in combination with glasses, contact lenses, intraocular lenses, refractive surgery or other ophthalmic or surgical corrections.
 fifteen
[17]
17. Use of the instrument according to claims 1 to 15 as a phoropter.

[18]
18. Use of the instrument according to claims 1 to 15 in combination with visual or psychophysical tests.
 twenty
[19]
19. Use of the instrument according to claims 1 to 15 to evaluate the tolerance of patients to simultaneous vision corrections or for the training of the patient prior to the implantation of simultaneous vision corrections.

[20]
20. Use of the instrument according to claims 1 to 15 to determine or select the parameters of a simultaneous vision correction at the time of its design or during the prescription or selection of the most appropriate correction for a given patient or for a patient group

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同族专利:

---

公开号 | 公开日

---

WO2017055656A1|2017-04-06|

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EP3357409B1|2020-05-06|

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EP3357409A4|2019-05-15|

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ES2797109T3|2020-12-01|

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US10213358B2|2019-02-26|

---

US20180271741A1|2018-09-27|

---

ES2610789B1|2018-02-07|

---

EP3357409A1|2018-08-08|

引用文献:

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CN111034284A|2017-08-11|2020-04-17|联想（新加坡）私人有限公司|Determining synchronization signal block positions|ES2346175B1|2009-04-08|2011-09-30|Consejo Superior De Investigaciones Científicas |INSTRUMENT FOR THE SIMULATION OF MULTIFOCAL OPHTHALM CORRECTIONS.|

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ES2373134B2|2009-08-28|2012-10-26|Universidad De Murcia|OPHTHALMIC INSTRUMENT FOR MEASURING OCULAR REFRACTION AND VISUAL SIMULATION, AND ASSOCIATED METHODS OF MEASURING OCULAR REFRACTION, SIMULATION OF OPHTHALMIC VISUAL SIMULATION ELEMENTS AND OBTAINING OPTICAL PARAMETERS.|

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US8042945B2|2009-10-06|2011-10-25|Hoya Corporation|Multifocal intraocular lens simulator and method of simulating multifocal intraocular lens|

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JP2011250981A|2010-06-02|2011-12-15|Hoya Corp|Multifocal lens simulator|

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JP2012068551A|2010-09-27|2012-04-05|Hoya Corp|Intraocular lens simulation device and simulation method|

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ES2396770B2|2010-10-20|2013-12-27|Sergio Oscar Luque|METHOD AND SYSTEM FOR SIMULATION-EMULATION OF VISION THROUGH INTRAOCULAR LENSES OR DEVICES PRIOR TO GIRUGIA|

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ES2535126B1|2013-10-01|2016-03-17|Consejo Superior De Investigaciones Científicas |MINIATURIZED INSTRUMENT SIMULTANEOUS VISION SIMULATOR|

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优先权:

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申请号 | 申请日 | 专利标题

---

ES201531397A|ES2610789B1|2015-09-30|2015-09-30|MINIATURIZED INSTRUMENT SIMULTANEOUS VISION SIMULATOR BY MASK GENERATION|ES201531397A| ES2610789B1|2015-09-30|2015-09-30|MINIATURIZED INSTRUMENT SIMULTANEOUS VISION SIMULATOR BY MASK GENERATION|

---

PCT/ES2016/070673| WO2017055656A1|2015-09-30|2016-09-27|Miniaturised instrument for simulating simultaneous vision by generating masks|

---

ES16850421T| ES2797109T3|2015-09-30|2016-09-27|Miniaturized instrument for simulating simultaneous vision by mask generation|

---

EP16850421.5A| EP3357409B1|2015-09-30|2016-09-27|Miniaturised instrument for simulating simultaneous vision by generating masks|

---

US15/763,986| US10213358B2|2015-09-30|2016-09-27|Miniaturised instrument for simulating simultaneous vision by generating masks|