WO2019151900A1 - Controllable anti-dazzle diffusion filter-2 (cadf-2) - Google Patents

Abstract

The invention relates to devices for protecting against dazzle and can be used to significantly increase traffic safety by completely eliminating dazzle, in particular dazzle experienced by drivers from the lights of oncoming and passing vehicles as well as from other sources of light. A controllable anti-dazzle filter CADF-2 comprising successively arranged optically transparent systems utilizing an optically transparent dielectric substance, the opposing surfaces of which are provided with systems of electrodes, wherein the surfaces of the optically transparent dielectric material/thin optically transparent substrates contain orienting elements, further comprises a signal processing and control system containing at least one sensor for registering the intensity and incident directions of the polarized components of external visible light passing through the filter to receptors of said external visible light, at least one decision-making processor, at least one position detector for detecting the spatial position of the receptors of external visible light relative to the filter, and at least one generating system, from an output of which control potentials are distributed among the systems of electrodes.

Description

 Controlled anti-glare scattering filter -2 (UPRF -2).

The invention relates to devices for protection against glare and can be used to significantly improve the safety of movement of land, air and other vehicles, due to the complete elimination of glare, in particular, drivers, headlights of oncoming and passing vehicles, as well as other

radiation sources.

 Known devices for vehicles using a filter to protect against radiation [1,2], as well as using a visor or glasses to protect against polarized and unpolarized radiation [3,4,5].

 The disadvantages of the known devices are large losses of received radiation [1], significant mutual illumination of the eyes when scattering radiation [2], requires at least two

liquid crystal (LC) films for scattering each of the polarization components of radiation [3], as well as

technological difficulties in constructing the optical filter system [4] and the mutual influence of the control potentials of closely spaced liquid crystal films [3,4,5].

The closest in technical essence and selected as a prototype is “Controlled anti-glare scattering filter - 1 (UPRF-1)” [5], containing controlled scattering radiation, an optically transparent filter, at least one receiver of external optical radiation, at least , one pupil position sensor for the eyes of the driver of the vehicle, a processor and a control unit. The disadvantages of the prototype:

 1. In most cases, only one of the polarizing components of the radiation is blinding in the reflected radiation, but the mutual influence of the control potentials of the closely spaced LCD films does not allow independent scattering of only one of the polarizing components of the radiation, which is blinding without affecting the other, is informative, or requires an increase in the distance between LCD films, and, accordingly, a significant increase in the thickness of the optical part of the filter and mass.

 The claimed technical solution in the annex to vehicles is aimed at creating an effective

 anti-glare filter with minimal loss and

 adaptive to blinding radiation sources.

1. This is achieved by the fact that, in contrast to the well-known "Controlled anti-glare scattering filter - 1 (UPRF-1)" [5],

containing sequentially installed optically transparent systems using an optically transparent dielectric substance - thin optically transparent substrates and sequences of liquid crystal films (LCDs), the opposite surfaces of which have electrode systems whose direction on the same surface differs from their location on another surface, and the surfaces are optically transparent

dielectric material - thin optically transparent substrates contain orientants, as well as containing a signal processing and control system, including at least one sensor for recording the intensity and directions of arrival of the polarization components of the external optical radiation passing through the filter to

at least one external optical radiation receiver a decision-making processor, at least one position sensor in the space of the external optical radiation receivers relative to the filter, and at least one formation system, from the output of which control potentials are distributed between the electrode systems of the corresponding liquid crystal films (LC) for local change in the properties of the zones defined by at least one decision-making processor, while, with the corresponding signal of the signal processing and control system, the molecules

liquid crystal films of the filter having an initial orientation in which external optical radiation passes through them unhindered, and located in the zones of passage through the filter to

receivers of external optical radiation, the intensity of which exceeds the set by the sensor for fixing the intensity and directions of arrival of the polarization components of the external optical

radiation threshold, under the influence of control potentials on

the corresponding electrode systems, form by means of at least one of the orientants in one, or in part, or in all successively installed liquid crystal films (LC), spatial optical anisotropy, scattering radiation passing through the filter, and in addition, contains at least at least one irradiator (7) operating in the optical or infrared range, as well as, on one side of each of the liquid crystal films (10), the electrode systems are made in the form of sequences in parallel on one of the surfaces of optically transparent substrates, between which there are liquid crystal films (10), systems of narrow stripes of networks, and, on the opposite side of each

of a liquid crystal film (10), in a direction that differs from the direction of arrangement of the electrode systems on another surface, for example, orthogonally, there are wide, optically transparent electrodes (13) or electrode systems, in the form

sequences of parallel deposited, on optically transparent substrates, systems of narrow stripes of grids, the cells of which are opposite, symmetrically, relative to the cells, systems of narrow stripes of grids on optically transparent substrates from the opposite side

liquid crystal films (10), while the size of each cell deposited on the optically transparent substrates of systems of narrow stripes of grids determines the size of the aperture of microlenses formed in the liquid crystal films (10), when the potentials are applied to the corresponding electrodes, in the controlled anti-glare

scattering filter - 2 (UPRF-2), between liquid crystal films containing electrode systems and scattering

orthogonal polarization components of the blinding radiation, when potentials are applied to the corresponding electrode systems, at least one optically transparent screening electrode is introduced (18).

 2. In addition, from the side of the liquid crystal film (10), systems of narrow electrodes (15) are additionally introduced, separated from the first by an optically transparent, dielectric insulating film.

 3. In addition, a system has been introduced that corrects the angles of scattering of radiation in the corresponding liquid crystal films (10),

 exceeding a given threshold in the horizontal plane,

 taking into account the distance between the radiation receiver and the filter.

 4. In addition, it contains a floating threshold installation system that determines the average intensity of the reflected

 the surface of the road radiation from the near zone and the total

the illumination at a given time, and calculates in accordance with this, and taking into account the adaptive characteristics of the driver’s eyes, the threshold for the inclusion of the formation system in the specified filter zones optical anisotropy, as well as the magnitude of the control potentials on the corresponding electrodes.

 5. In addition, the filter is installed at an angle to the passing

 radiation (Fig. 9), and contains a light absorber located in such a way that radiation reflected from the filter surface from the driver’s side falls on it.

 6. In addition, liquid crystal films (10), orientant, optically transparent electrodes (13), optically transparent

 a shielding electrode (18), and an optically transparent dielectric substance (11), between which liquid crystal films are enclosed, are optically matched to minimize the loss of transmitted radiation.

 7. In addition, from the output side contains a reflector (17) of external optical radiation (Fig.7).

 8. In addition, it contains a sensor for evaluating the average intensity of external optical radiation.

 9. In addition, it contains a spectral analyzer

 received external optical radiation.

 10. In addition, it contains a filter that corrects the spectrum of transmitted external optical radiation.

 11. In addition, it is made in the form of glasses and contains a case of glasses and an external unit, while some of the nodes of the signal processing and control system are installed in the case of glasses, and the other part, which has more weight, dimensions and power consumption, is installed in the external unit and introduced between them two-way automatic communication channel.

 12. In addition, the outer surfaces have an antireflection coating.

13. In addition, it contains a system for maintaining the temperature of the filter in the operating range. 14. In addition, it contains a system that monitors the condition of the driver of the vehicle, coupled with other emergency warning systems.

 15. In addition, an optically transparent filter is brought out

additional information necessary for the driver.

The proposed technical solution is illustrated using Figure 1 ... Figure 12:

 On figa shows the scattering of the filter (3) UPRF-2 external glare (1) when it exceeds a predetermined threshold.

 In FIG. lb shows the block diagram of the filter UPRF-2.

 1c shows a block diagram of a latch sensor

the intensity and directions of arrival of the polarization components of external optical radiation (DFIN), with the installation system

floating threshold, in which before the receiving matrix

an optical attenuator is installed to stabilize the brightness of the radiation reflected from the reference section of the road at a given level, taking into account external illumination.

 On figa, b, c shows fragments of electrode systems made in the form of sequences in parallel deposited on the surface of optically transparent substrates, between which are enclosed

liquid crystal films (10), systems of narrow stripes of nets (14).

 Figure 2 <1 shows fragments of additional systems narrow

electrodes.

 Figure 2e shows fragments of electrodes in the form of systems of narrow stripes of grids (14) and orthogonally located systems of wide, optically transparent electrodes (13), between which

liquid crystal film. On F.I. fragments of electrodes are shown in the form of systems of narrow stripes of grids (14) arranged mutually orthogonally, between which a liquid crystal film is mounted.

 Onr.2g, h, i shows fragments of narrow electrode systems,

containing taps - systems of narrow, short electrodes (14) [4].

 Figure 2] shows fragments of narrow electrode systems containing taps — narrow, short electrode systems (14) and orthogonally located systems of wide, optically transparent electrodes (13), between which a liquid crystal film (10) is installed.

 Figure 2k shows fragments of systems of narrow electrodes containing taps - systems of narrow, short electrodes (14) located mutually orthogonally, between which

liquid crystal film (10).

 Figure 3a shows a possible arrangement of the electrodes in the form of systems of narrow stripes of grids (14) and additional narrow electrodes (15) separated by an optically transparent insulating film (12).

 Fig. 3b shows a fragment of an LC film and a system of narrow, mesh electrodes.

 Figure 4 shows the scattering of radiation passing through the filter, formed in the liquid crystal film by a lens [10], using nematic LCD films with homeotropic

 orientation.

 Figure 5 shows a fragment of the sequences of LC films (10), with initially homeotropically oriented molecules, in which when potentials are applied to the electrodes of the filter zones, under the influence of electric field profiles,

formed by a system of narrow electrodes located on both of the sides of each LCD film containing systems of narrow stripes of grids (14) (Fig.2a, b, c,) or taps - systems of narrow, short electrodes (OHr.2g, h, i) [4], optical anisotropy is formed, leading to scattering radiation of the corresponding polarization

 components.

 Figure 6 shows a fragment of sequences of LC films (10), with initially homeotropically oriented molecules, in which, when the potential zones of the filter are applied to the electrodes of the filter, under the influence of electric field profiles,

 formed by a system of electrodes containing a system of narrow stripes of grids (14) (Fig.2a, b, c,) or taps - a system of narrow, short electrodes (Fig.2, 11D) [4] located on one side of the LCD films, and a system of optically transparent wide electrodes (13) located on the other side of the LCD films is formed

 optical anisotropy leading to radiation scattering

 corresponding polarization components.

 Figure 7 shows a fragment of sequences of LC films (10), with initially homeotropically oriented molecules mounted on a reflector (17), in which, when control potentials are applied to the electrodes of the corresponding filter zones, the radiation of the corresponding polarization components is scattered.

 On Fig shows a variant of the visor with an optically transparent filter that extends from it (3).

 Figure 9 shows the installation of the filter (3), at an angle to

radiation passing through it to eliminate possible glare from its surface on the driver’s side (4), using

retractable light absorber.

Figure 10 shows the near radiation zone, “A” is the road surface zone, the brightness of which and the general illumination is given by the support, regarding which the threshold for the glare protection system is set.

 On figa shows a variant of the visor with an optically transparent filter (3) that extends from it.

 Figure 1 lb shows a variant of combining the optical part of the filter UPRF-2 with the windshield of the vehicle.

 On Fig shows a graph of the scattering of glare radiation by the filter zones, at a threshold level that varies in accordance with the overall illumination and brightness of the reference region of the road surface, taking into account the adaptive characteristic of the driver’s eyes.

Figure 1 ... Figure 11 and in the text the following notation:

 1 - source of external optical radiation,

 2- filter zones, scattering rays of external optical radiation,

 3- optical filter system UPRF-2,

 4- receivers of external optical radiation (driver’s eyes),

5 - scattering plane of external optical radiation,

 6 - sensor for recording the intensity and directions of arrival of the polarization components of external optical radiation,

7- emitter, for illuminating receivers of external optical radiation,

 8- signal processing and control system,

 9 - position sensor in the space of the receivers of external optical radiation (pupils of the driver’s eyes),

 10 - liquid crystal films (LCD),

 11- optically transparent dielectric substance - thin optically transparent substrates,

12- optically transparent insulating film, 13 - systems of optically transparent wide electrodes,

14 - electrodes in the form of systems of narrow strips of nets or a system of narrow, short electrodes,

 15 - additional, narrow electrode systems,

 16- antireflection coating

 17- reflector

 18 - optically transparent shielding electrode,

 19- ambient light sensor,

 20 - data processing unit for sensors for fixing the intensity and directions of arrival of the polarization components of external optical radiation,

 21 - data processing unit for position sensors in the space of receivers of external optical radiation (pupils of the driver’s eyes),

22 - communication interface of the signal processing and control system with the optical filter system,

 23- input of the ambient light sensor,

 24- input installation of a floating threshold,

 25 - attenuator,

 26 - light absorber,

 27- lenses

 28- receiving matrix (s),

 29- output of the horizontal polarization component

radiation

 30- amplifiers

 31 - output of the vertical polarizing component of the radiation,

32 - distributor of polarizing radiation components,

33 - decisive device,

 34- orientant,

35- setting the parameters of the signal processing and control system. Thus, the controlled anti-glare scattering filter -2 (UPRF -2) (Figure 1) contains sequentially installed optically transparent systems using optically

transparent dielectric matter - thin optically

transparent substrates (11) and sequences

liquid crystal films (LC) (10), opposite

the surfaces of which have an electrode system (SE) (13,14,15), the direction of which on one surface differs from the direction of their location on another surface, the surfaces of the optically transparent dielectric substance (11) contain orientations, and also contains a signal processing system and

control, including at least one sensor for recording the intensity and directions of arrival of the polarization components of external optical radiation (DFIN) (6), at least one decision-making processor, at least one sensor

position in space of external optical receivers

radiation (D1111) (9), at least one formation system, as well as LC molecules (10) are formed by one of

spatial optical anisotropy, for each of the orthogonal polarization components of the external optical radiation passing through the filter, of the electrode system

made in the form of sequences of parallel deposited, on the surface of optically transparent substrates, between which are enclosed liquid crystal films (10), systems of narrow stripes of grids, the cells of which are opposite, symmetrically,

relative to cells, systems of narrow stripes of networks on optically transparent substrates on the opposite side of liquid crystal films (10), the size of each cell of systems of narrow stripes of networks determines the size of the aperture formed in liquid crystal films (10) microlenses, as well, contains systems of wide, optically transparent electrodes (13), and in addition, contains at least one

irradiator (7) operating in optical or infrared

in the range, at least one optically transparent shielding electrode is inserted (18), and, in addition, in parallel

electrodes (14), additional, narrow electrodes (15) are located, separated from the first optically transparent dielectric

insulating film (12), a system has been introduced that corrects angles in sequences of liquid crystal films (10)

radiation scattering, as well as the orientant orientates the liquid crystal molecules (10) in the same way, contains a system for setting a floating threshold, and settings for it, a threshold for activating an optical anisotropy formation system, filter (3) is installed at an angle to the transmitted radiation, and contains a light absorber, LCD - films, orientant and optically transparent dielectric substance - thin optically transparent substrates (11) are optically matched to each other, contains an external optical reflector (17)

radiation, contains a sensor for assessing the average intensity of external optical radiation, an analyzer of spectral composition, a light filter, is made in the form of glasses and contains a case of glasses and an external unit, the outer surfaces of the filter (3) have an antireflection coating (16), and also contains a temperature maintaining system 2 in the working interval, a system that monitors the state of the driver of the vehicle, interfaced with other systems

emergency warning and an optically transparent filter displays additional information necessary for the driver. The device operates as follows:

 The controlled anti-glare scattering filter - 2 (UPRF-2) (Fig. 1) is mounted in the vehicle (ground, air, etc.), while the filter (3) can be located in an assembled (folded) form so that if necessary, it could be introduced before the eyes of the vehicle driver (Fig. 11a), to protect it from external optical radiation of increased brightness, at a distance of, for example, 200 ... 1000 mm, or mounted on the windshield

vehicle or combined with the windshield (Figure 1 lb), or made in the form of glasses, as well as a lowering visor on the helmet, for example, a motorcyclist, and in addition, the filter (3) can be applied to passengers of the vehicle.

 At least one fixation sensor (receiver) of the intensity and directions of arrival of the polarization components of the external optical filter is installed on or near the filter holder (3)

radiation (DFIN) (6) passing through the filter to the receivers

external optical radiation (4), from a given sector of the front hemisphere, at least one position sensor in the space of the external optical radiation receivers (9) - the pupils of the driver’s eyes (4), and at least one irradiator (7) operating in optical or infrared, providing the necessary

Illumination of the pupils of the driver’s eyes to reliably determine their position in space. A signal processing and control system is installed on the holder or in the dashboard of the vehicle, as well as at least one decision-making processor and at least one formation system, from the output of which control signals are distributed between the electrode systems (13,14 ,15)

corresponding liquid crystal films (10), for local changes in the properties of zones specified by at least one decision-making processor.

 Position sensors in the space of optical radiation receivers (9) (DPP) - the pupils of the driver’s eyes can be performed, for example, using the technology of the Swedish company Tobii Technology, which developed such a system for vehicles for

improve road safety, which works equally with any driver, regardless of age, eye color, whether a person wears glasses or lenses, and in any conditions, from night driving to the bright sun.

 A similar system with a little refinement m. Applied in the tracking node position in a given sector of the review, dazzling

radiation sources (1).

 Narrowband can be installed at the sensor input

filters matched in spectrum with an irradiator / irradiators, which will increase the noise immunity of the system. Irradiators

illuminated radiation receivers (4) can operate in continuous mode, pulsed or have a different type of modulation, and the beam / rays of irradiators can scan the sector in which

radiation receivers (4), and position sensors of radiation receivers (9) in their work can use, for example, the red-eye effect. When applying the pulse mode, to eliminate the influence of external radiation on the operation of the system for determining the coordinates of the pupils of the eyes, the pupils, for example, can be highlighted through the frame, with subsequent subtraction of successive frames, and to eliminate

reflections from the lenses of glasses - the irradiator can emit one polarization, and the DPP can take orthogonal.

 In addition, position sensors in the space of the receivers

radiation (9) fix the geometric parameters of the receivers radiation (4), for example, the diameter of the pupils of the eyes of the driver, the relative parameters of which can vary with the expansion / contraction of the pupils and depending on their distance from the filter (3), and

 in accordance with this, as well as taking into account the speed of tracking systems for tracking the position of radiation receivers, a control device

 increases or decreases the scattering areas (zones) of the filter (3), which will optimize the information content of the space viewed through the filter.

 Intensity and arrival directions sensor

polarization components of optical radiation (DFIN) (6), can be performed using at least one color matrix, divided into two parts, in front of which are installed input lenses that transmit the orthogonal polarization components of external radiation, respectively, in different parts of the matrix, or can be performed using two matrices, in front of which lenses and an attenuator, controlled by a resolving device (RU), are likewise mounted (Fig. L s).

 The optical filter system (3) (Figure 1) contains optically transparent systems in series (Figure 5 ... Figure 7) using an optically transparent dielectric substance - thin optically transparent substrates (11) and sequences of liquid crystal (LCD) films ( 10) thickness, for example, 10 ...

150 microns, the opposite surfaces of which have electrode systems, which are made in the form of sequences

 parallel to the applied, on the surface of optically transparent substrates, between which there are liquid crystal films (10), systems of narrow stripes of grids (14) (Fig. 2a, b, c,, Fig. 5), for example, a width of 0.5 ... 2 mm each, or narrow electrode systems,

containing taps - a system of narrow, short electrodes (Figure 2, b, 1) [4], or optically transparent electrodes (13) (Onr.2eJ, Fig. 6) can be deposited on one side, for example, with a width of 0.5 ... 2 mm, the transparency of which can be higher than 97 ... 99% [7.8], whose location on one surface differs from their location on another surface, for example, are orthogonal.

 The surfaces of the optically transparent dielectric substance (11) contain orientants that specify the initial orientation of the LC molecules, for example, planar, homeotropic, or inclined, as well as the orientation of the LC molecules, which they acquire under

the influence of an electric field generated when applying the corresponding potential zones of the filter to the electrodes of the control potentials. For example, the initial homeotropic orientation of the LC molecules

installed by spraying on the surface of an optically transparent dielectric substance (11) carbon nanotubes, with

subsequent formation of an additional orienting relief, treatment with a surface electromagnetic wave (SEW)

[6].

 Thus, each of the polarization components of the external optical radiation passes through at least one

the liquid crystal film (10), coordinated with it, by means of an orientant, and the liquid crystal film molecules of the filter (3), with the corresponding control potentials of the signal processing and control system, having an initial orientation in which external optical radiation passes through them freely and located in the passage zones through the filter to the radiation receivers - the driver’s eyes (4) of the external optical radiation, the intensity of which exceeds the specified intensity and direction fixation sensor stroke polarization components of the external optical radiation (DFIN) threshold under control potentials on the corresponding electrode systems, form by means of one of the orientations in one, or in part of the films, or in all successively mounted LC films, spatial optical anisotropy, which partially or partially scatters the radiation passing through the filter [9, 10].

 The filter is based on the property of the lens to scatter the radiation passing through it, which is carried out by the formation of multiple microlenses in the specified zones of liquid crystal films.

In the controlled anti-glare scattering filter -2 (UPRF-2), on one side of each of the liquid crystal films (10), the electrode systems are made in the form of sequences

optically applied on one of the surfaces

transparent substrates between which are enclosed

liquid crystal films (10), systems of narrow stripes of nets

(Fig.2a, b, c) or narrow electrode systems containing taps - narrow, short electrode systems (FHG.2, 1I, Ϊ) [4], a, C

on the opposite side of each liquid crystal film (10), in a direction that differs from the direction of arrangement of the electrode systems on another surface, for example, orthogonally, are systems of wide, optically transparent electrodes (13) (Fig. 2e) or electrode systems, in the form of sequences

parallel to the applied, on optically transparent substrates, systems of narrow stripes of nets (Fig.2a, b, c), the cells of which are opposite, symmetrically, relative to the cells, systems of narrow stripes of nets on optically transparent substrates on the opposite side

liquid crystal films (10), while the size of each cell deposited on optically transparent substrates of systems of narrow stripes of grids determines the size of the aperture formed in IB

liquid crystal films (10) of microlenses, when applying potentials to the corresponding electrodes and can be, for example, 100 ... 600 microns, or narrow electrode systems containing taps - narrow, short electrode systems (nr.2g, h, i) [ 4], in which, under the action of control potentials along the perimeter of the cells, optical anisotropy is formed, and accordingly, the transmitted radiation is scattered in the vertical and horizontal planes, providing maximum attenuation of the transmitted radiation.

 Moreover, between the liquid crystal films (10),

containing systems of electrodes, and scattering the orthogonal polarizing components of the blinding radiation, when potentials are applied to the corresponding electrode systems, at least one optically transparent shielding electrode has been introduced (18).

 If it is necessary to disperse one of the polarization components of the radiation, a significant effect is possible

control potentials on an adjacent LCD film,

designed to dissipate the orthogonal polarization component of the radiation, which will lead to some scattering of this polarization component as well, which in some cases will worsen the useful, informative component of radiation passing through these filter zones, for example, in cases when solar or other radiation reflects from the wet surface of a road, water body, or other reflective surfaces, the blinding surface has a large area, while reflecting and dazzling the driver

mainly one of the polarizing components of radiation is horizontal. Dissipating only this horizontal polarization component of the radiation, the filter works in the corresponding zones as a polarizing filter, passes the second, non-glare, informative component of radiation without loss, and allows you to maintain good visibility of the road in this area.

 And accordingly, to reduce the influence of managers

the potentials of neighboring LC films scattering orthogonal polarization components, they must be spatially separated, and this will lead to a significant increase in thickness and weight of the optical part of the filter (3), which will complicate the design and is unacceptable, for example, when combining the filter with the windshield of the vehicle, installation a filter on a motorcycle helmet or glasses.

 In the case of numerous radiation sources, the brightness of which exceeds the set threshold, and / or extended sources of glare radiation of complex shape, the sequential supply of control potentials to the corresponding zones of the LC films will require considerable time, due to the inertia of the LC molecules, the switching on time of which is 20 ... 100 ms, and in addition, it is necessary to take into account the relaxation time of the LC molecules after removing the control potentials, which will require the resumption of the supply of potentials to the corresponding zones of the LC films This filter.

 Moreover, the radiation of these sources may be different

intensities, as well as non-polarized, partially polarized, or polarized in the vertical and / or horizontal planes, and accordingly, it is necessary to apply control potentials of various sizes to different zones of LC films scattering the orthogonal polarization components of radiation, which will lead to the mutual influence of control potentials on molecules neighboring LCD film, on areas that should not affect the radiation passing through the filter.

 Thus, the low speed of the electro-optical response for LCs, which is determined by the reorientation time of LC molecules, as well as the relaxation time of molecules upon removal of control potentials, will not significantly increase the clock frequency and simultaneously, sequentially control LC films,

scattering orthogonal polarizing radiation components, in cases of numerous and / or extended sources of glare radiation.

 Insertion of an optically transparent screening electrode (18) between LCD films (10) scattering orthogonal

polarizing radiation components, eliminate the effect

control potentials to an adjacent LCD film, and will allow simultaneously and independently to apply potentials to the electrodes of neighboring LCD films (10) scattering orthogonal

the polarizing components of the glare radiation, reducing the clock frequency, and also to make the optical part of the filter (3) thin and light, and if necessary flexible, which matters, and, from the point of view, the safety of the design of the optical part of the filter (3).

 Additionally, from the side of the liquid crystal film (10), systems of narrow electrodes (15) were introduced (Fig. 2c1), separated from the systems of narrow strips of networks (Fig. 2a, b, c) by an optically transparent, dielectric insulating film (12) (Fig. Behind).

Moreover, with insufficiently intense blinding radiation, the signal processing and control system supplies control potentials only to the corresponding, additional narrow electrodes (15), which form lens systems in the specified filter zones that substantially correspond to cylindrical lenses, scattering glare radiation in a vertical plane, excluding the ingress of this radiation into the neighboring eye of the driver. With increasing intensity of blinding radiation, the signal processing and control system connects to the operation of the system of electrodes, in the form of sequences in parallel, applied to the optical

transparent substrates, systems of narrow stripes of grids (14) (Fig. 2a, b, c), changing the potential value on them, depending on the intensity of the glare radiation, which leads to its scattering and

horizontal plane, thus increasing at

necessary, the scattering area to the maximum.

 And thus, for each of the orthogonal polarization components of the external optical radiation passing through the filter, in the corresponding filter zones, when the external optical radiation exceeds a predetermined threshold at the radiation receivers, under the influence of the control potentials, lens systems are formed that are coordinated with

the corresponding polarization component of the radiation,

cylindrical, scattering radiation in a vertical plane, and / or substantially corresponding to spherical, scattering radiation in both vertical and horizontal planes, providing maximum scattering (scattering area) of glare radiation.

 Moreover, for each filter zone formed by the control potentials, which scatters the external optical radiation,

exceeding a given threshold, for each polarization

component of this radiation, to the corresponding electrodes of the liquid crystal films, the formation system feeds

control potentials whose values can vary significantly, which will optimize the degree of scattering radiation exceeding a predetermined threshold in both vertical and horizontal planes, and install the filter on various

 distances from the radiation receiver, as well as when using

 separate filters for each eye, for example, in glasses or

 the visor of the motorcyclist will allow to obtain effective, controlled scattering of all sources of glare radiation, various

 intensity.

 Additionally, a system has been introduced that corrects

 corresponding liquid crystal films (10), scattering angles of radiation exceeding a given threshold in horizontal

 the plane, relative to the position of each pupil of the driver’s eyes, taking into account the distance between the radiation receiver and the filter to exclude, if possible (when the glare radiation is not large enough), a part of the scattered glare radiation from the neighboring scattering zone entering the pupil area.

 In this case, the sequential installation of controlled systems

 by means of electrodes of LCD films for scattering the polarizing components of glare radiation, with a minimum filter thickness, it is possible to obtain a controlled, independent for each scattering zone of the filter, attenuation of glare radiation at the receiver (driver’s eyes) by 10 ... 100 ... 1000 times or more .

 Table N ° 1 shows the reduction in glare on the pupils of the driver’s eyes depending on the distance (D, mm) to the scattering filter lenses, where a = 23 is the maximum scattering angle of the glare radiation when using one LCD film for each polarizing component of the radiation, and a = 45 - the maximum scattering angle of the blinding radiation when applying two, sequentially

installed LCD films for each polarization component of the radiation, with the possible partial passage of radiation near electrodes, in the UPF patent [3] it is solved by the mutual shift of the electrodes in these LCD films by half the aperture of the formed lenses.

 S1 / S2 is the ratio of the area of scattering of glare radiation to the area of the pupils of the eyes of the driver for angles of maximum scattering, respectively 23 and 45 degrees.

 In the initial state, in the absence of an external blinding

 radiation, control potentials are not supplied to the electrodes, there is no optical anisotropy in the LCD films and the filter (3) is transparent.

In the presence of external glare radiation and when it exceeds a predetermined threshold, the sensor / sensors for fixing the intensity and

 the directions of arrival of the polarization components of optical radiation (DFIN) (6) (Fig. 1c) outputs to at least one decision processor signals containing information about the intensity of the polarization components of the external optical radiation, the spectral composition and direction of their arrival, which, in accordance with this data and data from the sensor / sensors

 position in space of external optical receivers

 radiation relative to the filter (DPP) (9) builds in accordance with their coordinates between them (virtually) a straight line and

 defines points or zones of passage of this line through the filter (3), and then through at least one control device distributes control signals between the electrode systems

 (13,14,15), using, for example, the multiplex method or the active matrix addressing method using memory cells, so that on the way of the rays of external optical radiation to the radiation receivers - the eyes of the driver (4) of the vehicle of the LCD film molecule ( 10) in the corresponding zones of the filter UPRF-2 under the action of locally modulated by these signals

electric fields change their orientation in space, and thus, the data of the filter zone (3) acquire optical anisotropy for one or both polarization components, and, accordingly, the conditions for controlled scattering of external optical radiation by the formed lenses are fulfilled (Fig. 5 ... Fig. 7), and the potential changes on the electrodes (13 , 14,15), forming lens systems will lead to a controlled change in their focal length and, accordingly, the degree of scattering of glare radiation.

 Figure 4 shows the scattering of transmitted radiation

a lens formed in a liquid crystal film [10], using nematic LC films with a homeotropic

orientation, where for a pupil with a diameter of 8 mm, the diameter of the scattered area at a distance of 500 mm from the filter is 420 mm, and accordingly, the ratio of the scattering area of the blinding radiation to the area of the pupil of the eyes will be 2800.

 In order to facilitate the operation of the device and significantly reduce the clock frequency, control signals on the filter electrodes, it is possible to combine in the dynamics of the electrodes the zones or scattering zones into groups to which control signals are addressed, which are updated, supplemented with new segments (dots) or appear new zones, as well as exclusion from groups of non-renewable segments or zones, and, in addition, this will significantly reduce the requirements for the electrical conductivity of the electrodes.

 In addition, it contains a floating threshold installation system that determines the average intensity of the reflected

the surface of the road radiation from the near zone, comprising, for example, 10 ... 15 meters from the vehicle, and the total illumination at a given time, in continuous mode, and in accordance with this, and taking into account the adaptive characteristics of the driver’s eyes, calculates the threshold for activating the formation system in the specified zones of the optical anisotropy filter, as well as the value of the control potentials on the corresponding electrodes.

 Figure 10 shows the near radiation zone, “A” is the road surface zone, according to the brightness of which, taking into account the general illumination, a support is set relative to which the threshold for the operation of the anti-glare protection system is set, and, “B” is the receiving matrix zone (DFIN ) (6), which gives information about the level of the floating support - the average intensity of the reflected radiation at a given time by the area “A” of the road surface, a glare protection system that takes into account the adaptive characteristic of the driver’s eyes.

 In the dark, this area of the matrix receives the radiation of its own headlights reflected from the road surface at dusk, plus external, natural radiation, and in the daytime, mainly external, natural radiation.

 The DFIN can be performed, for example, using a single color matrix, or can be performed on two matrices, in front of which lenses and an attenuator are mounted.

 A color matrix is needed to identify such signals, such as traffic signals, “stop” - signals of vehicles moving in front, etc., for which the filter should be

transparent.

 As a signal level sensor, received from the reference zone, a separate photodetector can be used.

 Additionally, the setting of the parameters of the signal processing and control system (35) (Fig. La), as well as manual

threshold adjustment. It is possible to introduce rain sensors to automatically adjust the threshold level.

 Ambient light sensors determine the integral brightness of the radiation in a cone with an angle, for example, 120 ... 160 degrees.

 If necessary, information from the sensor (DFIN) can be entered into the storage device, for monitoring and fixing the road

the setting.

 To eliminate possible glare from the surface of the filter (3) from the driver's side (4), the filter is installed at an angle to the radiation passing through it (Fig. 9), for example, at an angle of 30 degrees relative to the vertical, and contains a light absorber that can be extended along with a filter located in such a way that radiation reflected from the surface of the filter from the driver’s side falls on it.

To increase the transparency of the filter, liquid crystal films (10), orientant, optically transparent electrodes (13), optically transparent shielding electrode (18), and optically transparent dielectric substance (11), between which are enclosed

liquid crystal films that are optically consistent with each other, as well as with liquid crystal films to minimize the loss of transmitted radiation.

 When installing the reflector of external optical radiation from the output side of the filter UPRF-2 (Fig. 7), it can be used on the vehicle as anti-glare side mirrors and rear-view mirrors, in which, similarly, under the influence of control potentials on electrode systems (13.14 , 15), in the filter zones specified by the processor (3) when the external optical radiation exceeds a threshold, lens systems with variable focal length are formed

distance scattering transmitted radiation, which is reflected from the output side of the filter, and again passes through the filter system (3) scattering this radiation, and the optical radiation of lower intensity, passes through the filter below the threshold (3) without changes, is reflected from the reflector (mirror) and passes to the optical radiation receiver, the eyes of the driver (4).

 And similarly to the filter of Fig. L, in the mirrors of Fig. 7, changing the focal length of the lens systems, through the control potentials on the electrodes, will allow you to adjust the intensity of the radiation passing to the receiver (4).

 At the same time, the signal processing and control system can be common for controlling mirror systems (Fig. 7) and for the filter of Fig. 1, located in front of the eyes of the driver (4) of the vehicle, in the front hemisphere.

The presented table N ° 2 (for vehicles with the main beam on) shows the ratio of the brightness of the oncoming radiation source scattered by the filter with Kf = 10 ³ , where Kf is the dimming coefficient of the dazzling radiation by the filter, to the brightness of the intrinsic radiation spot of the headlights of the vehicle, reflected from the road with Kd = 0.1, where Kd is the reflection coefficient of the roadway, for the scattering angles of light beams of the headlights of their own radiation - 10 degrees., and oncoming - 10 degrees., where Dc - distance in meters from the oncoming traffic Twa and Ds - distance in meters to the spot reflected from the road of their own radiation.

According to the table below, with maximum filter scattering, for example, Kf = 10 ³ , even in worse conditions - oncoming vehicles move with high beams on, drivers, without being blinded, can view the road at a distance of more than 100 meters, taking into account the fact that the maximum range of light intensity that corresponds to the dynamic range the human visual system is about 10,000: 1 (about 4 orders of magnitude).

 And when switching the headlights of vehicles from far to near, the beam lowers and illuminates the roadway at a distance of 50 ... 70 meters, while the brightness of the headlights practically remains the same and, accordingly, the brightness of the spot reflected from the roadway

does not change significantly, but the brightness of the headlights of the oncoming

vehicle, when you switch them to the dipped beam, decreases by at least an order of magnitude - the headlight dazzles not with a direct beam, but with diffused light. Based on what, the magnitude of the ratio of brightness, sources of oncoming radiation and the brightness of the intrinsic spot

the radiation reflected from the road shown in the tables can be reduced by at least an order of magnitude.

 Additionally contains a sensor for assessing the average intensity of external optical radiation (1), for example, natural

 emitters and reflectors (sun, clouds, road, vegetation, etc.), natural illumination in the twilight time, which will allow

 to optimize the work of the DFIN, changing the threshold level in relation to the adaptive characteristic of the driver’s eyes (4) to the illumination (Fig. 12).

 Additionally contains a spectral analyzer

 received external optical radiation (1), which can be used to analyze incoming information in order to

 excluding radiation scattering from useful and necessary

 information, for example, traffic signals of increased brightness, side lights, “stop” - signals of vehicles or other signals.

If necessary, change the spectral composition of the received radiation contains a filter that corrects its spectrum. UPRF-2 built using this technology can be made thin enough, which will allow to build on its basis

 dropping visor on a helmet, for example, a motorcyclist.

 When using a filter in the form of a visor on a helmet or glasses, the control unit, the decision-making processor and other components can be brought outside their design into an external unit, for example, installed directly in the vehicle dashboard, and an automatic, two-way communication between them can carried out, for example, by emission and reception of signals in

 infrared or other frequency range, which allows

 significantly ease their weight, dimensions, and with autonomous power and reduce power consumption. In this case, the external unit may comprise a control panel for filter operation modes.

 To reduce reflections from the outer surfaces of the filter, they contain an antireflection coating, for example, Nippon Electric Glass film, which will achieve surface transparency within 99.5%.

 When using the UPRF-2 filter in harsh climatic conditions, for example, by a motorcyclist in the cold season, a system was introduced to maintain the temperature of the filter (3) in the operating temperature range, where an optically transparent shielding electrode can be used as a heating element (18).

Additionally, it contains a system that controls the state of the driver of the vehicle according to the movement of the eyelids and the direction of view, coupled with other emergency warning systems, for example, an automatic braking system, which is a very reliable and accurate measure to alert the driver of the vehicle about the possibility of uncontrolled sleep or critical weakening of attention during movement. In addition, an optically transparent filter

additional information necessary for the driver to drive safely, for example, about the presence of other vehicles near their vehicles and their speed, duplication of instrument readings, etc.

 Thus, the filter URF-2 passes without loss polarized and non-polarized radiation to the radiation receivers - the pupils of the eyes of the driver (4) of the vehicle from any direction within a given viewing sector from the front hemisphere, and / or through the mirrors of the vehicle, if its intensity, below a predetermined threshold and at the same time scatters polarized and non-polarized radiation independently, from any direction within the specified viewing sector, if its intensity exceeds a predetermined threshold, and the degree of scattering depends on the brightness of each of the sources of external optical radiation.

Using the invention will allow:

Significantly increase the safety of vehicles by using the technologically advanced and efficient anti-glare filter UPRF-2, which independently scatters the polarizing components of the incoming radiation, the brightness of which exceeds a predetermined threshold and is transparent for other directions.

Table 1.

Table 2. For vehicles with “high beam” on.

LITERATURE.

1. US Patent 5.422.756. G 02 B 005/3, 05/18/1992.

 2. RF Patent 2.077.069, Cl, cl. 6 G02 C7 / 10, B60 J3 / 06, 04/10/1997.

3. RF Patent 2.530.172, cl. 7G02B5 / 30, B60J3 / 06, 05.20.2013.

 4. RF Patent 2.609.278, cl. 7G02B5 / 30, B60J3 / 06, 12/12/2015.

 5. RF Patent 2.607.822, cl. 7G02B5 / 30, B60J3 / 06, 04/15/2016.

 6. Kamanina N.V., Vasiliev P.Ya. About the possibility of obtaining

 homeotropic orientation of nematic elements when using nanostructures. Letters to the ZhTF, 2009, vol. 35, issue 11, pp. 39-43.

 7. Study of the growth of conductive single-wall carbon nanotube films with ultra-high transparency. Dachuan Shi, Daniel E. Resasco

Chemical Physics Letters 511 (2011) 356-362.

 8. Zinc oxide based solid solutions for transparent electrodes.

 Gaskov A.M., Vorobyova N.A., Zhukova A.A., Krivetsky V.V., Marikutsa A.V., Petukhov I.A., Shatokhin A.N.

 Department of Inorganic Chemistry, Moscow State University, 12.31.2014.

 9. High-resistance liquid-crystal lens array for rotatable 2D / 3D

autostereoscopic display.

 Yu-Cheng Chang, Tai-Hsiang Jen, Chih-Hung Ting, and Yi-Pai Huang.

Department of Photonics & Institute of Electro-Optical Engineering, National Chiao Tung University, Hsinchu 30010, Taiwan. 2014 Optical Society of America.

 10. An Autostereoscopic Device for Mobile Applications Based on a Liquid Crystal Microlens Array and an OLED Display. Jose Francisco Algorri, Virginia Urruchi del Pozo, Jose Manuel Sanchez-Pena, Jose Manuel Oton. September 2014.

Claims

 CLAIM.

 Controlled anti-glare diffusion filter - 2,

comprising sequentially installed optically transparent systems using an optically transparent dielectric substance - thin optically transparent substrates and sequences of liquid crystal films, the opposite surfaces of which have electrode systems whose direction on the same surface differs from their location on another surface, and the surface of the optically transparent

dielectric material - thin optically transparent substrates contain orientants, as well as containing a signal processing and control system, including at least one sensor for recording the intensity and directions of arrival of the polarization components of the external optical radiation passing through the filter to

external optical radiation receivers, at least one decision-making processor, at least one position sensor in the space of external optical radiation receivers relative to the filter, and at least one formation system, from the output of which control potentials are distributed between the electrode systems of the respective liquid crystal films for

local changes in the properties of zones specified by at least one decision-making processor, and, with the corresponding signal of the signal processing and control system, the molecules

liquid crystal films of the filter having an initial orientation in which external optical radiation passes through them unhindered, and located in the zones of passage through the filter to

receivers of external optical radiation, the intensity of which exceeds the specified intensity and direction fixation sensor the arrival of the polarization components of external optical radiation threshold, under the influence of control potentials on

the corresponding electrode systems, form by means of at least one of the orientants in one, or in part, or in all successively mounted liquid crystal films, spatial optical anisotropy, scattering radiation passing through the filter, and in addition, contains at least one an irradiator operating in the optical or infrared range, as well as, on one side of each of the liquid crystal films, the electrode systems are made in the form of sequences in parallel

applied to one of the surfaces of optically transparent substrates, between which liquid crystal films are enclosed, systems of narrow stripes of networks, and, on the opposite side of each

of a liquid crystal film, in a direction that differs from the direction of arrangement of the electrode systems on another surface, for example, orthogonally, are systems of wide, optically transparent electrodes or electrode systems, in the form

sequences of parallel deposited, on optically transparent substrates, systems of narrow stripes of grids, the cells of which are opposite, symmetrically, relative to the cells, systems of narrow stripes of grids on optically transparent substrates from the opposite side

liquid crystal films, with the size of each cell

applied to optically transparent substrates of systems of narrow stripes of grids, determines the size of the aperture of microlenses formed in liquid crystal films, when applied to the corresponding electrodes

control potentials, characterized in that between

liquid crystal films containing electrode systems and scattering orthogonal polarization components

blinding radiation, when applying potentials to the corresponding electrode system, at least one optically transparent shield electrode has been introduced.

 2. The filter according to claim 1, characterized in that from

a liquid crystal film, systems of narrow electrodes are additionally introduced, separated from the first by optically transparent,

dielectric insulating film.

 3. The filter according to claim 1 or claim 2, characterized in that a system is introduced that corrects the angles of scattering of radiation in the corresponding liquid crystal films that exceed a predetermined threshold in the horizontal plane, taking into account the distance between the radiation receiver and the filter.

 4. The filter according to claim 1 or claim 2, characterized in that it contains a floating threshold installation system that determines the average

the intensity of the radiation from the near zone reflected by the road surface and the total illumination at a given time, and calculates in accordance with this, and taking into account the adaptive characteristics of the driver’s eyes, the threshold for the formation of the optical anisotropy filter in the specified zones, as well as the value of the control potentials on the corresponding electrodes .

 5. The filter according to claim 1 or claim 2, characterized in that the filter is installed at an angle to the transmitted radiation, and contains a light absorber,

located in such a way that radiation reflected from the surface of the filter from the driver’s side falls on it.

 6. The filter according to claim 1 or claim 2, characterized in that

 liquid crystal films, orientant, optically transparent electrodes, optically transparent shielding electrode, and

an optically transparent dielectric substance, between which liquid crystal films are enclosed, are optically matched to minimize the loss of transmitted radiation.

7. The filter according to claim 1 or claim 2, characterized in that the output side contains a reflector of external optical radiation.

 8. The filter according to claim 1 or claim 2, characterized in that it contains a sensor for evaluating the average intensity of external optical radiation.

 9. The filter according to claim 1 or claim 2, characterized in that it contains

analyzer of the spectral composition of the received external optical radiation.

 10. The filter according to claim 1 or claim 2, characterized in that it contains

light filter, correcting the spectrum of the passing external

optical radiation.

 11. The filter according to claim 1 or claim 2, characterized in that it is made in the form of glasses and contains a case of glasses and an external unit, while some of the nodes of the signal processing and control system are installed in the case of glasses, and the other part, having a greater weight, dimensions and power consumption are installed in the external unit and a channel is introduced between them

two-way automatic communication.

 12. The filter according to claim 1 or claim 2, characterized in that the external

surfaces have an antireflection coating.

 13. The filter according to claim 1 or claim 2, characterized in that it comprises a system for maintaining the temperature of the filter in the operating range.

 14. The filter according to claim 1 or claim 2, characterized in that it contains a system that monitors the condition of the driver of the vehicle,

coupled with other emergency warning systems.

 15. The filter according to claim 1 or claim 2, characterized in that an additional information necessary for the driver is displayed on the optically transparent filter.