DE102014107587B3 - Electronic glasses - Google Patents

Abstract

It is suggested glasses for a wearer with at least one eye, with a spectacle frame (F) and two lenses. The lenses are liquid crystal cell (LC) whose transmission can be changed by a suitable control. The glasses have sensors (IL, IR) for measuring the brightness of the visible light impinging on them, the sensors being arranged on the eye side of the spectacle lens. The sensors measure the brightness through the lenses in the direction of the wearer. Furthermore, the goggles have a closed loop, with there being a predetermined target value for the control loop (MC), which determines the brightness on the eye of the wearer. The actual value used by the control circuit is the brightness measured by the sensors on the eye of the spectacle wearer. With such glasses, the brightness for the eyes of the wearer can always be maintained in real time at a constant level, even with fast and strong changing ambient brightness.

Description

Field of the invention

The invention relates to electronic glasses.

State of the art

The light intensity passing through a light modulator, the so-called transmission, can be electrically controlled with the aid of various liquid crystal cells (TN, STN, Fe-IC, etc.) available on the market in such a way that at least 2 states are achieved, namely transparent or transparent Opaque dark, as is the case with popular 3D active TV glasses.

According to this basic idea, first attempts were made in the sixties to "electronic sunglasses" to provide the wearer of such glasses variable transmission.

So z. B. the DE 10 2012 217 326 A1 a sunshade with an optical transmission variable by means of an electrical signal. The sunglasses have an eye-mounted sensor which measures the light striking the glasses and generates the necessary signal to control the transmission. In brighter light, the glasses darken automatically.

The DE 199 07 334 A1 describes an electrochromic gradient shutter using liquid crystals.

Control instead of closed-loop control

The previously known electronic sunglasses work with pure controls, ie the photo sensors are often "outside", so that only the brightness is measured, which is incident on the glasses from the outside (sz B US 5 172 256 A ).

Accordingly, quasi "blind", d. H. via characteristic curve, which is based only on pure empirical values (look-up table, Kennline, etc.), via an actuator (amplifier / driver) an LCD according to light or dark switched - often only in 2 discrete brightness levels (eg glasses transparent or with X% dark tint).

Even if this control would work continuously, so "anlog", d. H. For each brightness value measured outside, a certain gray level would be generated on the LCD, so it is and remains a "blind control" since the true brightness passing through the LC is always unknown.

Too few and misplaced photosensors

In addition, there are often too few sensors whose direction of reception is completely unspecific (pointing forward or towards the sky). This often leads to completely wrong and even opposite reactions of the glasses. For example, if the wearer of the goggles looks into a dark viewing area (dark corner), but at the same time the goggles are caught by a stray beam of sunlight (through random reflections on objects or through moving leaves in the forest, creating a fine, variable chiaroscuro Pattern), so the LC will be dark, although it should actually be bright, because the wearer wants to see the dark area.

These "non-smart glasses" thus lead to dangerous malfunction or malfunction, which unfortunately cause the exact opposite of what should actually be achieved, so deteriorate the view in the worst case.

• – indem oftmals nur ein Fotosensor oder zumindest zu wenige Fotosensoren eingesetzt werden.
• – nur ein LC für beide Augen verwendet wird, d. h. keine unabhängige 2-Kanal-Steuerung für rechtes und linkes Auge getrennt vorgenommen wird.
• – bei starkem Gegenlicht (z. B. entgegen einer tief stehenden Sonne) keine Eigenlichtquelle zur Verfügung steht, die dem Schließen der Shutter entgegen wirkt.

This deterioration of visibility is even enhanced by 3 effects:

• - By often only a photosensor or at least too few photosensors are used.
• - Only one LC is used for both eyes, ie no independent 2-channel control for the right and left eye is made separately.
• - In strong backlight (eg., Against a low sun) no self-light source is available, which counteracts the closing of the shutter.

task

The object of the invention is to achieve an improvement in the field of electronic brightness-controlled spectacles.

solution

This object is achieved by the inventions having the features of the independent claims. Advantageous developments of the inventions are characterized in the subclaims. The wording of all claims is hereby incorporated by reference into the content of this specification.

In the following, individual process steps will be described in some places. The steps do not necessarily have to be performed in the order given, and the method to be described may also have other steps not mentioned.

All of the above problems are solved with "smart glasses" consisting of at least one closed-loop real-time PID loop, but preferably consisting of 2 completely independent control circuits of this type, namely one for the left eye and the left shutter and one for the right eye and the right shutter.

In order for a closed-loop control loop to be realized, at least one photosensor must be "in-line" per eye (per control loop), namely in such a way that it looks through the shutter in the direction of sight, like the human eye, and thus the "actual brightness " measures.

In control engineering, this is called the "actual value". The photosensor thus takes on the role of the eye. So he measures the "true brightness" that falls into the eye as a proxy for the eye, and not just any random external brightness.

Furthermore, at least 2, or better, 3 photosensors per eye are used by this type of photosensors whose positioning spans a coordinate system, for example a triangle on whose corner the statistical mean value of the pupil comes to lie - which is usually identical (in the case of non-squinting people) is with the point of the straight ahead view (see sketch).

With the aid of a triangulation calculation (Pythagoras or similar geometric calculations), the average brightness with respect to this statistical mean value or this straight-ahead view can then be calculated and used as "actual value" for the control.

In addition, "several internal photo sensors per eye" have the advantage that this redundancy preserves measurement safety, even in case of accidental contamination (fly on photosensor) or accidentally amplified light (random reflection).

As is known from general control engineering, there is next to the "actual value" also the "setpoint" - also called set point - which is initially set with a kind of potentiometer or similar "adjuster" so that the eye or the pupil diameter is constantly dark adapted remains - similar to a relatively strong sunglasses, z. B. with protection level III (S3, 8-18% transmission).

The controller or the entire controlled system is so fast that the control process can no longer be perceived by the human eye, ie. H. the incoming brightness to the eye is always constant, according to the target value, no matter how outside the brightness changes.

It is therefore a so-called real-time control loop in which in the steady state (correct PID parameterization) the so-called delta (control deviation) - ie the difference between setpoint and actual value - is always zero.

Real-time control circuit for permanent dark adaptation of the eye

While this type of real-time control loop, where the bias is always zero, is well known, it has never been used with sunglasses.

However, this rule only works if the glasses are absolutely light-tight with respect to light from the outside - ie from the eyewear similar to a "diving goggles" or "goggles" or "tight-fitting large glasses with wide side bars and light protection from above and below".

There are currently no such light-tight sunglasses with real-time loop, with which one can slowly open the human pupil with the help of an electric potentiometer or similar adjuster a) and literally "turn up" until it is 75% open over normal diameter in daylight - and b) due to the real-time control can remain constant on this diameter, so that it is quasi "quiet", no matter how the brightness may change outside.

This happens separately for each eye, although in the start routine each eye initially gets the same setpoint, e.g. B. 100 lux on the right eye (R) and left (L).

Changes in the setpoint

However, this DC connection (R = L) and constant circuit (R = L = const.) Of the two setpoints is to be assumed only for a better understanding and to start, since this is often taken as a starting scenario in control engineering.

In reality, however, the setpoints R and L are changed relatively slowly (eg, 2 to 100 times slower than the control) and also deliberately subject to slight differences, e.g. For example, 10% more transparency on the left and 10% less transparency on the right. The reasons for this are explained below.

Variable setpoint

At least one outdoor sensor per eye (outside L, see OL in 1 , Outside R, s. OR in 1 ) records roughly and comparatively slowly (eg within 1-2 seconds) the daylight situation in the time average and determines whether there is a bright day, covered day or indoor situation.

This is necessary because the dynamic range in terms of illuminance during the day covers a range of 100 lux to 100,000 lux, ie about a factor 10,000, a simple LC cell but possibly only a factor 1000 to 5000 includes (contrast ratio).

Therefore, with a variable setpoint determined by the outdoor sensor (bright day, covered day, ...), the "working point" of the IC cell is shifted to the correct range during an initialization routine at power up - e.g. B. on a very bright day from initially 100 lux fix on the eye to 300 lux fix on the eye.

In addition, this setpoint initiated by the outdoor sensor is always changed quickly and dynamically even when the controller is at the so-called "lower or upper stop", ie the control deviation can no longer be zero because the controlled variable at the IC cell or the transparency ( completely open) or transmission has reached (not too high) a value that can no longer be increased.

This should not be the case regularly, as it is already the idea to keep the eye permanently dark-adapted; but when lighting situations change overall "globally", the set point can be changed in such a way (LC all the way to or completely open), taking account of electronically stored empirical values and information from the outside sensors and from the inside sensors shortly before reaching the so-called controller stop be that the controller remains in "normal operation" and does not really reach this stop, d. H. behaves logarithmically or similarly nonlinearly in the broadest sense, but allows a gentle and controlled closure of the iris due to the increased passing brightness (eg, when looking directly into the sun).

Variable setpoint to increase the dynamic range of the liquid crystal

After all, the iris of the eye, via real-time control loop or via absolutely constant brightness on the eye, should not be condemned for all time to complete inactivity, but their dynamic range by LC cell expanded and expanded.

It should be noted, however, that this "dynamic range adjustment" should only be used in exceptional cases; During normal operation, the pupil is set to a fixed, relatively dark value (eg 75% above normal diameter), as already described above, so that the dark-adapted eye is immediately and immediately available within one millisecond when entering a dark room.

HDR viewing (HDR = high dynamic range, higher contrast range)

In addition, the two setpoints L and R can have defined, but slight differences, eg. B. 5% to 30% more transparency on the left and on the other side accordingly reversed, so that the brain from the two slightly different images in the perception can imperceptibly recapture, but with a slightly higher contrast range (dynamic range), which in the photograph as HDR photography is known (2 differently exposed photos are copied into each other).

In the present claim, therefore, "real-time HDR vision" is invented and defined. The prerequisite is that the contrast difference is not too extreme, so "imperceptible" remains - which is why above from about 1% to 60%, preferably 5% to 30% is mentioned. Higher values> 30% are not excluded, but then appear shorter in time, at least in such a way that the brain can imperceptibly construct a new image with a higher contrast range.

This is also the basis for this claim that human perception is intervened by means of intelligent software algorithms - which is the case for all further claims below.

Consideration of physiological functions of the optic chiasm C

The highest and most complex form of this type of electronic driving consists in the consideration of right-left contralateral pupillary refraction in a "swinging flash-light test" (SWIFT) -like illumination situation that is physiologically mediated by the crossing left-right nerve signal exchange in the optic chiasm of the brain.

Specifically, this means that in the case of normal people with no asymmetries in the contralateral pupillary affinity (such as the relative afferent pupil defect - RAPD) in normal operation, NO neuronal stimuli are produced for exactly the same set electronic values for both eyes (L = R = const.). Information is exchanged crosswise, since the brightness is always constant in both eyes.

There are 3 types of exploitation of this effect:

• 1) An increased control signal (eg increased darkening) on a channel (L or R) at identical setpoints (R = L = const.) Signals an asymmetrical lighting situation, eg. B. excessive outside light on the channel in question.

• 2) Absichtliches Betreiben in dem HDR-Differenzmode kann dazu führen, dass der Kanal, der heller (transparenter) geschaltet wird, insbesondere wenn dieser versehentlich oder absichtlich zu schnell und zu umfänglich transparent geschaltet wird (delta t, delta T relativ hoch), eine kontralaterale Pupillenkontraktion auf dem anderen Kanal hervorruft.

The microcontroller of this channel tells the other microcontroller or the state machine of the other channel to almost reach or override the channel. The underexposed side can then open.

• 2) Deliberate operation in the HDR differential mode may result in the channel being switched brighter (more transparent), especially if it is accidentally or intentionally switched too fast and too transparent (delta t, delta T relatively high) induces contralateral pupil contraction on the other canal.

To take account of this effect (to compensate = negative feedback or possibly intentionally amplify = positive feedback), the other channel is gently and appropriately controlled so that on the one hand there is an improved view of the other eye, but so gentle that there is no renewed contralateral transmission to the initially affected channel (starting point) - d. H. Swinging of the entire system consisting of both pupils and two software-controlled channels is prevented, depending on a) external light situation, b) operating points of the two controllers and c) transients / lighting changes on the respective channels (bright day, cloudy day), proximity to the controller stop ( completely open, completely closed) and difference between the controls.

3) Medical and psycho-pathological indications:

• 3a) For patients with a relative afferent pupil defect (RAPD), the right-left pupil behavior pattern of the patient can be stored in the software of the microcontroller, so that when operating in the two above-mentioned modes (1 and 2) their pupil behavior with the correct LC Transparency is taken into account in such a way that the perceived brightness is always constant or corresponds to certain desired setpoints.
• 3b) For patients with a legally prescribed right-left vision training (after stroke, etc.), one side can be switched to either permanent or alternately darker or brighter according to certain temporal patterns.
• 3c) For emergency responders (eg soldiers in action) who have an acutely increased level of adrenaline and thus generally dilated pupils, the software can reduce (slightly darken) the transmission by command (button), thus enhancing visual perception Brightness is more pleasant.

Positioning the photo sensors

The photosensor has a certain distance (typically 1-3 mm) to the IC cell, so that due to its opening angle, the effectively considered LC area is larger than the chip area. This leads to a better averaging of the brightness and a more accurate / stable measurement in the case of selective IC domain formation, or in the case of punctual contamination on the opposite side of the LC cell.

For safety reasons and for thermal reasons anyway an outer eyeglass protective glass, which also makes up the design and face of the glasses, placed at a distance of 1-3 mm in front of the LC cell, so that such punctual contamination (small flies, dust grains, etc.) have no influence on the LC and certainly have no influence on the photosensor. (see sketch).

Safety check parallel to the control

In addition, all internal photocells are designed at least twice or even triple - but not only to calculate the average brightness in the most probable location means of the pupil (straight ahead, as described above in "Triangulation / Pythagoras"), but also for security reasons by using "purely logical comparison "(For example, 2 sensors show similar brightness and only one shows no brightness) the software may simply ignore a particular photo sensor in case of its contamination or defect and only the two functioning photosensors are considered.

Ie. The software consists not only of permanently calculating controller components, but also of purely logical safety routines (separate state machines), which constantly ensure the function of the glasses in parallel to the rules - not only as part of an initialization routine at power up, but actually during of normal operation.

In this context, it should be noted that the most error-prone glasses of this type (for automotive applications) include ASIL NORM approved dual or tri-core processors that test both hardware and software for errors.

Further details and features will become apparent from the following description of preferred embodiments in conjunction with the subclaims. In this case, the respective features can be implemented on their own or in combination with one another. The possibilities to solve the problem are not limited to the embodiments. So include For example, range information always includes all - not mentioned - intermediate values and all imaginable subintervals.

An embodiment is shown schematically in the figure. In detail shows:

1 a schematic representation in a sectional plan view of the electronic glasses.

The following is partial to 1 Referenced. Everything below is always valid for 1 eye (right or left, also called "a channel"). A channel consists of at least one LC cell (or several cells connected in series - so-called "stacking" - but typically 2 cells in series) which depending on the application suitable, fast and high-contrast LC material (TN, STN, Fe-LC ) includes.

The cell, which is more distant from the human body, is referred to as "distal," and that on the eye as "proximal."

One to three complex photosensors IL1, IR1 are located behind the proximal cell at a certain distance (typ. 1-3 mm) and record the light incidence through the LC cell LC 1L, LC 2L, LC 1R, LC 2R in the viewing direction. like the human eye, with a single photosensor again consisting of at least 3 sensors spanning an orthogonal xyz coordinate system - the vector (1, 1, 1) pointing in the direction of view.

As an alternative to the x-y-z photosensor, it is possible to use a photosensor array which, like a compound eye (also called fly eye or oculu compositi), has significantly more than just 3 orthogonal channels.

Each channel can measure the brightness in a large dynamic range so that a "rough image" is transmitted to the microprocessor.

As an alternative to such a "coarse image" is also a system with optical lenses imaging system, also called camera, provided with significantly higher resolutions - z. For example, a 5 MPix camera with the same miniature size, which does not exceed a few square millimeters, similar to those already used in smartphones and notebooks. The image transmitted to the processor from such a camera is finer in resolution: the dynamic range and linearity for measuring brightness are ensured by the use of highly dynamic chip materials, similar to analytical medical photography.

For the sake of security only, at least 3 such complex photo sensors are used per eye E (L), E (R) (channel) (x-y-z or facets or camera).

Wavelength neutral - by day and by night.

All the above-mentioned photosensors may be physically designed as photodiodes, phototransistors, photocells, etc. In any case, all have in common that they react color neutral by taking into account the color sensitivity curve of the eye, the so-called V-lambda function according to DIN 5031.

Such photocells are used for example in photography for color-neutral exposure measurement - which offer a few manufacturers.

Depending on the ambient brightness - measured by an external sensor OL, OR, or derived from the manipulated variable and setpoint of the controller MC - a look-up table (LUT) can be included in the computation algorithm, which measures the V 'values, at main darkness includes and accounts for night vision so that the so-called Purkinje effect (the increased blue sensitivity at night) is taken into account.

Consideration of individual and age-dependent glare sensitivity There are empirical studies on the glare sensitivity of humans, in particular angle-dependent and age-dependent [Adrian and Bhanji 1991 - Illumination Engineering Society of North America]

Freeform lens

Proposed is the physical-mechanical implementation of o. G. Formula in a corresponding free-form lens made of transparent material (glass, plastic, liquid, etc.), which translates the eye sensitivity formula into concrete physics so that you can use this, attached to a photosensor, for direction-sensitive measurement of brightness, as it also makes the human eye.

In other words, an "artificial eye" is created, which is as sensitive to glare as a human eye via the angle of incidence.

• 1) Berücksichtigung der V-Lambda-Funktion und V'-Lambda-Funktion (Purkinje-Effekt bei Nacht)
• 2) Berücksichtigung der winkelabhängigen Blendungsempfindlichkeit.

The approach to an "artificial eye" is now supported by two factors:

• 1) Consideration of the V-lambda function and V'-lambda function (Purkinje effect at night)
• 2) Consider the angle-dependent glare sensitivity.

FREE-FORM CHANNEL

Instead of this lens, a black channel shaped correspondingly by free-form calculation can also be used for simplicity (essentially a bore), at the end of which said photocell is located, so that this photocell obtains an aperture angle which corresponds to the sensitivity of the human eye.

SOFTWARE WITH CAMERA

Instead of a free-form lens and instead of a free-form channel (see above), the formula for glare sensitivity can ideally be implemented purely as an algorithm in the software, which also receives the high-resolution / high-dynamic image of the camera, since in a camera image, the direction information and brightness per pixel is included.

The camera image can then be weighted with individual (age-dependent) weighting formulas, especially as one's personal age or other individual preferences or medical indications / recommendations for glare sensitivity via any man-machine interface (touch on glasses, USB PC software Interface, smartphone app via (Bluetooth) radio) - be it permanently stored or different depending on the application and user (available profiles: sport and / or user profiles)

Eyetracker simple type ET (L), ET (R)

By analogy with the above-mentioned photosensors or camera types that simulate a human eye, a second sensor is placed inside the glasses, at approximately the exact same location where this sensor is located, but exactly in the opposite direction, ie to the eye turned around, watching the eye.

Ideally, this sensor can thus be on the back of the aforementioned sensor, or slightly offset next to it, depending on the spatial design.

In any case, this sensor observes the human eye, and in analogy to the above sensor types (photocell with lens or in bore or combined, compound eye with many photocells, or as imaging camera) various types of sensors can be used, starting from relatively simple and inexpensive Photo sensors or facet sensors to higher-resolution imaging camera systems.

In the simplest case, the viewing direction is only roughly captured. In particular, the zinc right movement of the eye can be detected even on the white part of the eye (dermis), especially in younger people with wide eyes, by using a coded infrared light barrier.

Infrared light is not perceived by the eye, but reflected differently by the eye, depending on the viewing direction. The coding of the IR source is necessary so that it is not confused with other light sources and reflections on the receiver side.

The coding does not have to follow a (secret) key, but in the simplest case can be cyclic, e.g. B. 10 kHz rectangle with known frequency and phase angle. From the frequency, but especially the phase position, a phase-sensitive detector (PSD), also called boxcar amplifier, after low-pass integration over about 10 cycles, so with at least 1 kHz make a very accurate amplitude measurement with respect to the transmitter signal, even then if this is "deeply hidden" in the noise of other IR signals.

This is just one example of a simple eye tracker. You can also determine the pupil position with a very similar method - also in reflection, but then with respect to the absorption in the pupil (quasi black hole) - instead of the reflection on the white dermis.

Since photoelectric retro-reflective sensors are very cost-effective, such sensors can be mounted both on the inside of the eye (near the nose) and on the outside of the eye (near the bedroom), possibly even in the center of the eye (looking up / down) - that is quite 2 up to 3 sensors.

Several such sensors increase the measuring accuracy with respect to the viewing direction. Ideally, however, an eyetracker is used that uses a tiny high-resolution imaging camera similar to that used in smartphones or notebooks no larger than a few square millimeters.

This camera detects the pupil position with respect to the viewing direction and thus all angles.

CORRELATION CALCULATION from photosensors and eyetrackers

In this claim, the direction and brightness information of the photocells / camera are now mathematically correlated with the viewing direction by software.

Correlated means, for example, that first the viewing direction (angular coordinates) is taken as the output, then at the same time (in real time) the incident brightness is measured and controlled at exactly the same angle with the camera looking through the IC cell.

Since this is a real-time PID control loop in which the control deviation is always zero, the brightness in the viewing direction will always be constant and always constant - namely according to the setpoint set (= setpoint value).

If this control worked very precisely, which would be possible using high technology, the pupil on the major axis would never experience a brightness difference.

This could lead to artifacts in the perception, so that the software deliberately slows down a bit or readjust the brightness in slight angled increments - eg. For example, only when the user really looks closely into the left-most blind source (eg, auto-reverse) will it be instantly controlled for constant brightness, otherwise, if the pupil moves only slightly in the middle, from which no counter-glare light moves, only to this brightness constantly regulated.

In other words, the above-mentioned individual and age-dependent glare sensitivity function stored in the software is placed over the signal of the receiving camera looking forward - like a template (eg, multiplicative weighting) - and although this camera is NOT like an eyeball is moved, but just rigidly mounted straight, is "quasi-inside", due to the eye tracker signal, this template in this artificial eye mitverschoben according to the eyeball movement!

This practically creates an artificial eye which incorporates the individual viewing angle-dependent glare sensitivity and serves as the reference variable (also called "actual value") for the real-time PID control loop.

It is up to the programmer and user to make the algorithms smoother or stronger, depending on the sport, application, etc.

Pulse shaping in LC cells

• Type 1: Both IC cells can be cells that are transparent in a de-energized state to ensure normal visibility in the event of a system or power failure.
• Type 2: For high-security applications where there is a permanent risk of glare in the work area (LASER laboratory, arc welding, etc.) LC cells can be used, which work the other way around; H. which are switched completely dark in the dead state, and are released transparent only by pressing a safety switch or the like.
• Type 3: The third possibility consists of a mixture of type 1 and type 2 cells, ie a cell that is permeable in a de-energized state and a closed cell. This arrangement can be used to improve the edge steepness in the rising AND falling edge of an optical pulse, in the sense of transparent switching for a fraction of a second in the form of a rectangular pulse on the time axis (high-slope rectangle on the optically measuring oscilloscope image ).

The advantage is lower crosstalk and other contrast-reducing artifacts (crosstalk) in synchronous applications with one or more subscribers.

quoted literature

cited patent literature

• DE 10 2012 217 326 A1
• DE 199 07 334 A1
• US 5 172 256 A

quoted non-patent literature

• Adrian, W. and Bhanji, A. (1991). "Fundamentals of disability glare. "A glimpse of stray light in the eye as a function of the glare angle and age." Proceedings of the First International Symposium at Glare, Orlando, Florida, p. 185-194.

Claims (16)

Spectacles for a wearer with at least one eye, with 1.1 a spectacle frame (F); 1.2 at least one spectacle lens; 1.2.1 wherein the at least one spectacle lens has a liquid crystal cell (LC) whose transmission can be changed by a control; 1.3 a sensor (IL, IR) for measuring the brightness of the incident light on it; 1.3.1 wherein the sensor is arranged on the eye side of the spectacle lens; 1.3.2 wherein the sensor measures the brightness through the at least one spectacle lens in the direction of the spectacle wearer; 1.4 a closed loop (MC, LC, IL, IR); 1.4.1 where there is a predetermined target value for the control loop that determines the brightness on the eye of the wearer; 1.4.2 where the control loop uses as actual value the brightness measured by the sensor; 1.5 an eye tracker (ET), which determines the viewing direction of the eye; 1.6 wherein the brightness sensor (IL, IR) 1.6.1 has an imaging system with a camera or 1.6.2 at least 3 sensors that span a coordinate system, or 1.6.3 a compound eye; 1.7 wherein the brightness sensor determines the brightness of the visible light striking it from the viewing direction of the eye; and 1.8 wherein the brightness control is designed such that it takes place depending on the brightness in the direction of the spectacle wearer. Spectacles according to the preceding claim, characterized in that the liquid crystal cell (LC) is designed such that it can change its transmission from 90% to 10% and from 10% to 90% in a maximum of 10 ms. Spectacles according to one of the preceding claims, characterized in that the spectacle frame seals the at least one eye of the spectacle wearer in a light-tight manner with respect to the ambient light. Spectacles according to one of the preceding claims, characterized in that the target value of the control loop predetermines an eye brightness of 20 to 400 lx. Spectacles according to one of the preceding claims, characterized in that the brightness of the ambient light is derived from the desired value and a control signal of the control loop. Spectacles according to one of the preceding claims, characterized by at least one further brightness sensor (OL, OR), which is arranged on the side of the spectacles facing away from the eye and determines the brightness of the ambient light. Spectacles according to one of the two preceding claims, 7.1 wherein the setpoint of the control loop can be changed depending on the brightness of the ambient light; and 7.2 wherein the change of the setpoint is at least a factor of 10 slower than the regulation of the transmission of the liquid crystal cell. Spectacles according to the preceding claim, characterized in that: 8.1 the change in the desired value takes place in predefined stages; 8.2 wherein the stepwise change of the setpoint by at least a factor of 100 is slower than the regulation of the transmission of the liquid crystal cell and 8.3 has a hysteresis in its course. Spectacles according to the preceding claim, characterized in that the control is designed such that it reacts instantaneously to extreme brightness values. Spectacles according to one of the preceding claims, marked by 10.1 two spectacle lenses for two eyes of a spectacle wearer; 10.2 two eye-side sensors for measuring the brightness of the visible light striking the respective eye; and through 10.3 one loop for each eye. Spectacles according to the preceding claim, characterized in that the nominal values for the two eyes differ from one another by 1% to 60%. Spectacles according to claim 10, characterized in that the regulation of the brightness for the other eye is taken into account in the regulation of the brightness of the visible light striking an eye. Spectacles according to claim 1, marked by 13.1 light sources, which are arranged on the side facing away from the eye of the glasses; 13.2 wherein the light sources are controlled depending on the viewing direction of the wearer. Spectacles according to one of the preceding claims, characterized in that the measured values of the sensors and / or setpoint values of the control circuits and / or the brightness of the surroundings derived therefrom are connected to a geo-coordinate signal of a geographic-coordinate receiver and recorded. Spectacles according to one of the preceding claims, characterized in that: 15.1 the at least one spectacle lens has a further liquid crystal cell whose transmission can be changed by a suitable control, wherein the further liquid crystal cell is arranged in the viewing direction behind or in front of the liquid crystal cell. A method of controlling the brightness of the visible light incident on at least one eye, comprising the steps of: providing a goggle for a wearer having the at least one eye, the goggle comprising: 16.1 a goggle frame; 16.2 at least one spectacle lens; 16.2.1 wherein the at least one spectacle lens has a liquid crystal cell (LC) whose transmission can be changed by a suitable control; 16.3 a sensor (IL, IR) for measuring the brightness of the visible light striking the sensor; 16.3.1 wherein the sensor is arranged on the eye side of the spectacle lens; 16.3.2 wherein the sensor measures the brightness through the at least one spectacle lens in the direction of the spectacle wearer; 16.4 a closed loop (MC, LC, IL, IR); 16.4.1 where there is a predetermined target value for the control loop, which determines the brightness on the eye of the wearer; 16.4.2 the control loop taking as actual value the brightness measured by the sensor; 16.5 an eye tracker (ET), which determines the viewing direction of the eye; 16.6 wherein for the brightness sensor (IL, IR) 16.6.1 an imaging system with a camera or 16.6.2 at least 3 sensors spanning a coordinate system or 16.6.3 a compound eye is provided; 16.7 wherein the brightness sensor determines the brightness of the visible light striking it from the viewing direction of the eye; 16.8 wherein the brightness control is dependent on the brightness in the direction of the wearer.

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