DE102014208981A1 - Contextual tint of glasses and a HMD - Google Patents

Abstract

Disclosed is a method for tinting a pair of glasses, in particular HMD, the glasses comprising: a darkening layer, which are arranged on the glasses so that it is within the field of view of the user when wearing the glasses as intended; wherein the obscuring layer is adapted to occupy different states with different transmittances of light in the visible region, the obscuring layer being arranged to switch between the states by electrical driving; The method comprising: determining the position and movement of the glasses or a vehicle in which the glasses are located; Determining the future time at which a predefined brightness of the environment is likely to be present, depending on the particular position and movement and a digital map in which building structures are recorded; Activating one of the predefined brightness assigned state of the obscuring layer depending on the specific time.

Description

The invention relates to a method for tinting a pair of spectacles or a head-mounted display (HMD) and corresponding spectacles themselves.

Sunglasses are widely used nowadays. Such goggles typically include glasses (which also include plastic glasses) that are both UV opaque and tinted, thereby filtering some of the visible light. Also known are adaptive glasses with glasses whose tint changes automatically depending on the light. These adaptive glasses are often not suitable for use in vehicles because the necessary for the automatic tinting UV radiation is already absorbed by the vehicle windows. In addition, these adaptive spectacles have the disadvantage that the tint changes with changes in brightness only with a time delay. Even with versions of automatic tinting glasses, which are suitable for use in vehicles, thus resulting in the disadvantage that, for example, when driving in the sunshine when entering and exiting a tunnel, the tint of the sunglasses is changed only with delay. So it happens that when entering a tunnel, the sunglasses are still heavily tinted and the visibility for the wearer of the glasses is correspondingly deteriorated, which can endanger the road safety.

Also known today are data glasses (sometimes called head-mounted display), with the help of the wearer of the data glasses information can be displayed. The data glasses are worn like ordinary glasses, which is used as a visual aid on the head. Compared to ordinary glasses, however, the data glasses include a display that is located near the user's eyes when wearing the data glasses. The display can include two partial displays, one for each eye. On the display, information may be displayed to the user in the form of text, graphics or mixtures thereof. In particular, the display can be partially transparent (also called transparent), that is to say configured in such a way that the wearer can also recognize the surroundings behind the display. Particularly preferably, the information is displayed to the wearer contact-analog, which is sometimes referred to as augmented reality. In this case, the carrier of the data glasses, the information is displayed at a location that is oriented to the location of an object in the area, so for example, adjacent to the object or this superimposed. The display of the data glasses also includes an artificial light source, with the aid of which the display is made visible to the user. In the case of a display transparent to the user, the presentation of the display is superimposed by the light of the environment behind the display. If the brightness of the environment is comparatively high compared to the brightness of the display, it may happen that the display on the display is hardly or not at all recognizable to the user. The relative contrast of the display is therefore insufficient. Conversely, the brightness of the display may be too large and dazzle in an otherwise relatively dark environment. Using data glasses in traffic can endanger traffic safety.

In the publication WO 2012/039877 A1 There is disclosed a data goggle comprising an LCD display used for dimming and another display for displays. The darkening takes place depending on the displayed images.

The object underlying the invention is the provision of an automatically sounding glasses whose tinting is adapted as quickly as possible to a changing ambient light.

The object is solved by the subject matters of the independent claims. Advantageous developments are defined in the dependent claims.

One aspect of the invention relates to a method for tinting a pair of eyeglasses, the eyeglasses comprising: a blackout layer arranged on the eyeglasses such that, when the eyeglasses are properly worn, it is within the field of vision of the user; wherein the obscuration layer is adapted to assume different states with different transmissivities for light in the visible region, wherein the obscuration layer is adapted to switch between the states by electrical drive. The method includes: determining the position and movement of the glasses or a vehicle in which the glasses are located; Determining the future time at which a predefined brightness of the environment is likely to be present, depending on the particular position and movement and a digital map in which building structures are recorded; Activating one of the predefined brightness assigned state of the obscuring layer depending on the specific time. The darkening layer may be, for example, an electrochromatic layer and in particular comprises two partial layers; one for each eye of the user of the glasses. Activation is understood herein to mean the maintenance of a condition. The predefined brightness can be defined as a luminous flux or by specifying certain building structures.

It is therefore proposed herein to change the tint of the glasses at the time when the brightness of the environment is likely to change. For the prediction of the time, the position and movement of the glasses or the vehicle in which the glasses are located, is taken into account. The brightness of the environment refers to the environment of the glasses, which includes the environment of the vehicle. For the method according to the invention, only the surroundings of the vehicle can be taken into account.

The method can be carried out by a pair of glasses themselves, in particular data glasses, or data glasses together with a vehicle.

In the case where the method is performed by data glasses alone, the data glasses comprise a positioning means (for example a GPS / GLONASS / Galileo receiver) and a navigation device with a digital map (for example a navigation program). With the help of the movement and position of the eyeglasses detected by the positioning means, future positions are estimated by the navigation unit. If at least some of these positions (according to the digital map) are located in an area in which a certain ambient brightness is expected, activation of a darkening state corresponding to the expected ambient brightness is provided. For example, it can be seen that a pedestrian with the glasses is running from an open road into an underpass and, accordingly, the tint of the glasses are taken back.

When the method is performed together with a vehicle, the vehicle includes the positioning means and the navigation unit. These determine the time at which a certain ambient brightness of the spectacles (and thus of the vehicle) is expected. This point in time communicates the navigation unit (preferably wirelessly) to the data glasses. Alternatively, a signal can be sent to the data glasses directly at the time itself, that the state should be changed or which state should be taken.

The building structures typically include tunnels and underpasses. In preferred developments, underpasses, parking garages, garages or houses themselves can also be included.

In a further development, the activation of a state requires a previously known period of time; wherein the time period is taken into account in determining the future time and whether the blackout layer is already in the state to be activated. For example, it is proposed here to select the start time for the state change in such a way that the state change has already taken place when it enters the region of changed ambient brightness. Alternatively, the start time can also be selected so that the state change or the duration of the state change only partially, for example, to 50%, completed or expired.

In a preferred embodiment, the activation of the state of the glasses is dependent on the measurements of a brightness sensor of the glasses or of the vehicle in which the data glasses are located. The consideration of the sensor can be done in different ways. For example, the state switching can only take place if the expected change in the ambient brightness actually occurs, that is to say measured with the aid of the sensor. The switching of the state can be done immediately when the changed brightness is measured. An otherwise for actuations based on the measurements of brightness sensors typical delay time to confirm the brightness change can be omitted. Furthermore, the switching of the state of the spectacles may also depend on whether the change of the ambient brightness occurs as expected according to the building structure. If, for example, the change is below a threshold value, or if the new ambient brightness does not reach a limit value, the switchover can be dispensed with. For example, a tunnel can be artificially illuminated particularly intensively, so that a reduction in the hue of the darkening layer is not necessary.

In a preferred embodiment, the glasses are data glasses, i. The glasses include a partially transparent display with light source whose brightness is changed depending on the specific time. In this way, an adjustment of the brightness of the display light source and thus the representations on the display is achieved in accordance with the ambient brightness. On the one hand glare of the user of the data glasses and on the other hand a too low relative contrast is avoided. Compared to a control of the light source brightness alone via a brightness sensor, the method proposed here offers the advantage that the adaptation of the light source brightness can be made faster. It is not necessary to wait for further measurements of the brightness sensor to determine a change in the ambient brightness with sufficient certainty.

In another aspect, smart glasses include: a blackout layer disposed on the goggle so as to be within the field of vision of the user when worn properly; wherein the obscuring layer is adapted to have different states each occupying different transmissivities for light in the visible range, wherein the obscuring layer is adapted to switch between the states by electrical control; A control unit, wherein the control unit is configured to: receive an indication of when or when the blackout layer is to be switched to the first or second state from a remote unit; Outputting a command to switch the blackout layer at the time of the received indication. The control unit of the data glasses may be further adapted to the steps of the above-mentioned methods.

BRIEF DESCRIPTION OF THE DRAWINGS

1 schematically shows a data glasses and a navigation unit of a vehicle according to an embodiment.

2 shows a flowchart of a method according to an embodiment.

DETAILED DESCRIPTION OF THE EMBODIMENTS

1 schematically shows a data glasses 1 and a navigation unit 5 a vehicle (not shown) according to an embodiment. The data glasses 1 each includes a partial display 2 for every eye of the wearer of the data glasses. Looking behind this ad is before each partial ad 2 a darkening layer 3 arranged. In this example, the blackout layer exists 3 from an electrochromatic glass. Both the ad 2 as well as the layer 3 are with a control unit 4 connected to the data goggles, which is set up for wireless communication using the Wi-Fi and Bluetooth standards. The data glasses 1 is for use in a vehicle (in 1 not shown). The vehicle includes a navigation unit 5 with positioning means. The positioning means comprise an antenna 7 with which GPS, GLONASS and / or Galileo signals can be received. These signals are evaluated by electronic circuits of the positioning means, so that finally the determined position to the navigation unit 5 can be issued. The navigation unit 5 also includes a database 6 in which a digital map is stored. The digital map provides information about streets and building structures. The navigation unit is also for wireless communication via WiFi or Bluetooth using the antenna 8th set up. In operation, the positioning means continuously determine the position of the vehicle and report it to the navigation unit 5 , Step S1 in FIG 2 , Furthermore, the navigation unit receives information about the movement of the vehicle from the on-board sensor system of the vehicle. This information is linked to determine the position and movement of the vehicle. Based on the information about the road on which the vehicle is located and the determined movement of the vehicle future positions of the vehicle are calculated. For each of these positions, the existing building structure is analyzed. For example, it can be stated that the vehicle will drive into a tunnel in the future.

Each building structure is assigned a predefined brightness and, based on this brightness, the state of the blackout layer is determined on the basis of an assignment. The assignments are predefined and stored in the navigation unit. In one embodiment, the brightness is indicated by the building structure, for example tunnels.

If the ascertained brightness fulfills a predetermined criterion (predefined brightness), for example below a limit value, the time of entry into the corresponding building structure and the state to be activated are determined (step S2 in FIG 1 ) and wirelessly transmitted to the data glasses. The predetermined criterion may also be dependent on the previous ambient brightness. In this case, in particular, the sensor measurement of a brightness sensor of the vehicle can be taken into account. If the measurements of the sensor show that the current ambient brightness is already below the limit value, no signal is transmitted to the data glasses.

The data glasses activate the received state at the predetermined time (step S3 in FIG 2 ).

In this way, changes in the ambient brightness can be anticipated and changed without delay to the occurrence of the change, the tint of the data glasses accordingly. Especially when driving in tunnels, underpasses or car parks can be avoided so that the driver of a vehicle perceives the environment worse, at least for a short period of time.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• WO 2012/039877 A1 [0004]

Claims (8)

 Method for tinting glasses the glasses comprising: A blackout layer, which is arranged on the glasses so that it is in the user's field of vision when wearing the glasses as intended; wherein the obscuring layer is adapted to occupy different states with different transmittances of light in the visible region, the obscuring layer being arranged to switch between the states by electrical driving; The method comprises: Determining the position and movement of the glasses or a vehicle in which the glasses are located; Determining the future time at which a predefined brightness of the environment is likely to be present, depending on the particular position and movement and a digital map in which building structures are recorded; Activating one of the predefined brightness assigned state of the obscuring layer depending on the specific time.  The method of claim 1, wherein the building structures comprise one or more of tunnels, underpasses, parking garages, garages or houses.  The method of any one of the preceding claims, wherein switching from one state to another requires a known amount of time; wherein, in determining the future time, the time duration and whether the darkening layer is already in the state to be activated is taken into account.  Method according to one of the preceding claims, wherein the activation of the state of the glasses from the measurements of a brightness sensor of the glasses or the vehicle in which the data glasses is located, at or after the specific time is dependent.  Method according to one of the preceding claims, wherein the glasses are a data glasses, namely a pair of glasses, which includes a display with light source.  The method of claim 5, further comprising: Adjust the brightness of the light source depending on the specific time.  Data glasses, comprising: A blackout layer, which is arranged on the glasses so that it is in the user's field of vision when wearing the glasses as intended; wherein the obscuring layer is adapted to occupy different states with different transmittances of light in the visible region, the obscuring layer being arranged to switch between the states by electrical driving; A control unit, wherein the control unit is configured to: Receiving an indication of when or when the blackout layer is to be switched to the first or second state from a remote unit; Outputting a command to switch the blackout layer at the time of the received indication.  Data glasses, comprising: A darkening layer, which is arranged on the data glasses in such a way that, when the data glasses are worn correctly, it is within the field of vision of the user; wherein the obscuration layer is configured to assume a first state and a second state; wherein the darkening layer in the first state is more transparent to light in the visible region than in the second state; wherein the blackout layer is configured to switch between the first and second states by electrical drive; A control unit, wherein the control unit is configured to: Determining the position and movement of the glasses or a vehicle in which the glasses are located; Determining the future time at which a predefined brightness of the environment is likely to be present, depending on the particular position and movement and a digital map in which building structures are recorded; Activating one of the predefined brightness assigned state of the obscuring layer depending on the specific time.

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