COLLIMATING DISPLAY SYSTEM FOR A HELMET

Abstract

A display system providing in a moving device operator's field of view all required visual information in form of the image projected into optical infinity, realized by using located in a moving device operator's helmet the autonomous optoelectronic system including the display module comprising: the light-emitting micro display, the collimating lens, the flat semitransparent reflector, fixed on the lens case and located in front of the a moving device operator's eye so that to observe the luminous informational image projected into optical infinity against the external situation background. Said reflector is movably mounted in two positions: working and distant from the face. The lens assembly including the micro display and bracket with the reflector is equipped with an adjustment bracket allowing to place it in front of right or left motorcyclist's eye. A camera and a photo sensor measuring the background brightness are mounted on the helmet body.

Claims

1. (canceled)

2. (canceled)

3. The collimating display system for a helmet of claim 4, wherein the system is fixed in the helmet with an adjustment bracket, wherein the system is located in the helmet at a safe distance from a moving device operator's head and the semitransparent reflector is connected to the lens by an additional bracket, providing the possibility of placing the lens with the micro display and the semitransparent reflector in front of the moving device operator s right or left eye with possibility of an individual adjustment of the lens with a micro display and semitransparent reflector for comfortable viewing of an image within the angular field of view of the collimating display system and makes it possible to move the semitransparent reflector relative to the lens from the working position to the non-working position at a remote distance from the moving device operator s head both before putting on and before removing the helmet to reduce the risk of injury to the viewer and damage to the semitransparent reflector.

4. A collimating display system for a moving device operator the system comprising: a helmet, a Head Up Display apparatus located inside the helmet, said apparatus comprising a microprocessor and a display module, said display module comprising a collimating optical system with a lens, a flat semitransparent reflector, and a light-emitting micro display providing full volume of visual information required for operating the device in a form of a luminous image projected into optical infinity, a Wi-Fi signal digital generator, and a TV camera directed to a rear hemisphere wherein the light-emitting micro display is connected with the microprocessor, the flat semitransparent reflector is coupled to the collimating optical system; and the flat semitransparent reflector's location is adjustable relative to the collimating lens; the flat semitransparent reflector is directly optically coupled to the lens and located in front of one of the moving device operator's eves, allowing the moving device operator to observe the luminous image, projected into optical infinity against a background of an external space within a full angular field of view of the collimating optical system; wherein angular dimensions of the luminous image are equal to the full angular field of view of the collimating optical system at a distance to the moving device operator's eve; and the collimating optical system is designed so that the light-emitting display screen is located in a focal plane of the lens, said lens projecting the luminous image from the screen into optical infinity; wherein all motion parameters and systems status of the moving device are displayed on the periphery of the full angular field of vision, leaving the central part of the angular field of view without uploaded graphical information to monitor a path of the moving device, on the background of the external environment, and wherein said TV camera generates visual information about an external situation in the rear hemisphere, in the form of a collimated image of luminous information pictures in a lower part of the wide-angle field of view of the collimator optical system.

5. An imaging unit for a collimating display system, said unit designed as a separate structural unit located in a helmet between a helmet shell and a head, of a moving device operator and comprising a microprocessor and a display module, said display module comprising a collimating optical system with a lens, a flat semitransparent reflector, and a light-emitting micro display providing full volume of visual information in a form of a luminous image projected into optical infinity, wherein the light-emitting micro display is connected with the microprocessor, the flat semitransparent reflector is coupled to the collimating optical system; and the flat semitransparent reflector's location is adjustable relative to the collimating lens; the flat semitransparent reflector is directly optically coupled to the lens and located in front of one of moving device operator's eves, allowing the moving device operator to observe the luminous image, projected into optical infinity against a background of an external space within a full angular field of view of the collimating optical system; wherein angular dimensions of the luminous image are equal to the full angular field of view of the collimating optical system at a distance to the moving device operator's eve; and the collimating optical system is designed so that the light-emitting display screen is located in a focal plane of the lens, said lens projecting the luminous image from the screen into optical infinity; wherein all motion parameters and systems status of the moving device operator are displayed on the periphery of the full angular field of vision, leaving the central part of the angular field of view without uploaded graphical information to monitor an environment.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0019] FIG. 1A and FIG. 1B show functional scheme of the system.

[0020] FIGS. 2A and 2B show variants of information pictures observed by the motorcyclist within the angular field of view of the display system under two operating modes:

[0021] rear view TV camera is switched off—FIG. 2A,

[0022] rear view TV camera is switched on—FIG. 2B.

[0023] FIG. 3 Layout scheme embodiment of the helmet with the elements of the display system;

[0024] FIG. 3A shows the section A-A, FIG. 3

[0025] FIG. 3B shows the section B-B, FIG. 3.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENT OF THE INVENTION

[0026] FIG. 1A and FIG. 1B show the functional scheme of the proposed display system. The display system includes the helmet 1 with located in it display module 2, containing an electronic control unit—microprocessor 3 and a light-emitting micro display 4, e.g., OLED, on a screen 5 of which the primary informational image of specified brightness is formed, and a collimating optical system 6, projecting said informational image into optical infinity and providing for the driver ability to see it against the external situation picture background without re-accommodation and re-adaptation of visual apparatus needing. The miniature photo camera 7 intended for photographic recording of the external situation in traffic direction and the photosensor 8 for measuring of brightness of the ambient external background in frontal hemisphere are installed on the helmet and connected to the microprocessor 3. Power supply of the display module 2 is provided by located in the helmet accumulator 9. The accumulator 9 is connected to the wireless automatic control device 10, which, depending on charge level of the accumulator 9, is switching on or off the wireless charging device 11, located on the motorcycle body and connected to its' accumulator 12. FIG. 3 shows two placement options for specified wireless automatic control device 10. Wireless connecting of the display module to appropriate sensors of input and control signals is provided by wi-fi technology using a digital wi-fi signal generator 13, located on the motorcycle body. Power supply of the digital generator 13 is carried out by the motorcycle accumulator 12 also. Connected to the digital generator 13 via serial interface USB, the sensors of displayed informational parameters and data of controls include, e.g., the following: [0027] rear-view TV camera 14, [0028] speedometer 15, [0029] engine speed sensor 16, [0030] fuel sensor 17, [0031] real-time roll angle sensor 18, [0032] GPS receiver 19, [0033] control panel, located on the left handlebar of the motorcycle 20, [0034] control panel, located on the right handlebar of the motorcycle 21.

[0035] The list of displayed information parameters, including text, warning and reference information, can be changed or supplemented. At the same time type, size and location within the display system field of view of above informational images are entered into a program of the microprocessor 3 in advance. It should be noted that several sensors can be placed in the wi-fi signal generator 13 and integrated into it. To operatively manage volume and content of the information picture, formed by the display system, the following embodiment is suggested: to install on the left and right steering handles of the motorcycle the remote controls provided with appropriate switching elements, e.g., round or square buttons, that allows the driver in tactile way both to input the required informational parameters in the field of view and disable unnecessary ones when driving a motorcycle in various modes. To decrease the number of switching elements, located on the remote controls, some buttons are multifunctional depending on various types of pressing e.g., a single short or long press of the button or consecutive short pressing of one button several times provide the execution of the corresponding functions of the display system. To discern the buttons from one another they are painted in different colors and illuminated under night conditions in different way. At the same time, the most frequently used buttons are located on the remote controls in more accessible for the fingers places.

[0036] To provide operational control of the volume and content of the information picture image generated by the display system, other options are possible to be used. For example, it is possible to use voice control with voice commands in form of single words or phrases pronounced by the driver. In this case, the main condition is to have access to the Internet connection. By use of this voice commands the algorithms are entered that set operations required to control the volume and content of the information picture formed by the display system. The commands and response algorithms are pre-entered to the software of the system.

[0037] FIG. 2 shows the information pictures viewed by the motorcyclist within the angular field of view of the display system under two operating modes:

[0038] rear view TV camera is switched off, FIG. 2A;

[0039] rear view TV camera is switched on, FIG. 2B.

[0040] When the TV camera is switched off, FIG. 2A, a speed indicator 22 (sensor 15) and engine speed indicator 23 (sensor 16) are depicted as numerals and located in upper peripheral parts of the angular field of view. In this case they occupy minimal part of the angular field of view and do not obscure the central area. It is preferable to locate the fuel indicator under the engine speed indicator in the left part of the field of view. It can be carried out in form of linear digitalized scale 24 with the movable index 25 (sensor 17), indicating the level of fuel in the tank of the motorcycle. The indicator of roll angle 26 (sensor 18) can be represented by numerical value and a sign of the roll angle in the right lower part of the field of view and the GPS data 27 (sensor 19) is located between the indicators of roll angle 26 and speed 22.

[0041] When the TV camera is being switched on, FIG. 2B, the rear view TV image 28 is appearing in the lower part of the field of view and GPS data (see FIG. 2A, p. 2′7) is being switched off temporarily. It should be noted that if there is an angle of roll 26 currently then the TV image in the field of view of the display system is being turned by use of the software at the same angle in such way that the driver is perceiving the rear view without the roll relative to the road in motorcycle's traffic direction.

[0042] The FIG. 3 shows the layout embodiment for the helmet with the elements of the display system. The collimating optical system 6 (shown conditionally at the FIG. 1) contains a collimating lens 29 and a flat semitransparent reflector 30. A micro display 4 is installed on a case of the collimating lens 29 in such way that the screen 5 of the micro display is combined with the focal plane of the lens, which projects the luminous image from the screen 5 into optical infinity. The semitransparent reflector 30 is attached to the case of the lens 29 with a bracket 31 and located in front of the driver's eye 32 so that the driver is able to watch within the angular field of view 33 of the collimating optical system projected into optical infinity luminous informational image against the background of external situation picture in traffic direction. The dimensions of the reflector 30 on horizontal and vertical are not exceeding 25 mm with thickness 2 mm. At the same time, the angular field of view 33 of the display system is not less than 15 ? vertically and 20 ? horizontally. The display system design provides the ability to move the bracket 31 with the reflector 30 at a remote distance 34 from the driver's face by switching to the off-position both before putting on and before removing the helmet, that simplifies the helmet using and reduces the risks of injury for the driver and damage of the reflector.

[0043] The lens 29 is fixed on the helmet 1 housing by an adjusting bracket 35 at a safe distance from the driver's eye 32. The design of the bracket 35 provides the following capabilities:

[0044] to place the lens 29 module (with fixed on it micro display 4, the reflector 30 and the bracket 31) in front of the driver's right or left eye as preferred;

[0045] to carry out individual adjusting of the lens 29 module (with fixed on it micro display 4, the reflector 30 and the bracket 31) for each driver required for comfortable viewing of full informational picture formed by the helmet-mounted display system.

[0046] To carry out measurement of brightness of ambient background the photosensor 36 is located on the upper frontal part of the helmet in response of the signals of which the microprocessor 3 fulfills in real-time mode the appropriate adjusting of brightness of formed image of informational picture providing optimal image contrast against the ambient background under which the comfort perceiving is ensured for both the luminous informational picture and the external situation picture. To carry out photo shooting and video recording of road situation picture in the motorcycle's traffic direction a miniature camera 37 is installed on the frontal upper part of the helmet and provided with video recording option (similar to that used in modern smartphones). The photosensor 36 and the camera 37 are located in such way that an optical axis 38 of the camera and an optical axis of the photosensor are parallel to the line 40 passing through the center of the angular field of view 33 of the collimating optical system and

[0047] horizontal and vertical of the video frame of the camera 37 are located parallel to the horizontal and vertical of the informational picture.

[0048] If required, to provide the complete video registration of the motorcycle's moving process and the helmet-mounted display system functioning the real-time informational picture can be superposed to the photo image or video footage of the external situation picture that was fixed in the same place and with the same angular dimensions as it was observed by the driver at the same fixed time moment.

[0049] The helmet-mounted display system for the motorcycle works as follows: the current input data from the respective sensors and controls (14-21) are fed to the microprocessor 3 (FIG. 1) via the Wi-Fi communication channel. In accordance with the program symbolic graphical information is plotted during the time of “revers of the beam” which is equal to several milliseconds depending on selected TV standard, the signals, generated by the microprocessor 3, enter the micro display 4, which forms on the screen 5 corresponding primary image of the information picture of a certain brightness taking into account the signal from the photosensor 38. Since the volume of graphical symbolic information from the sensors 14-19 is small the image plotting can be carried out by functional method, allowing to reduce the speed of image plotting and due to this get more higher brightness of symbols image under conditions of high brightness of the external background. This is especially important because the brightness of the symbolic images of said parameters should be high enough to provide their confident readability under any ambient light conditions. Formed on the screen 5 by use of the projecting lens 29 and the semitransparent reflector 30, the luminous image is projected into optical infinity in the motorcycle traffic direction and is observed by the motorcyclist within the angular field of view 33 of the collimating optical system against the external situation picture without needing of re-accommodation and re-adaptation of vision.

[0050] The microprocessor 3 and the accumulator 9 are the most bulky elements of the helmet-mounted display system. To improve balancing of the helmet this elements are installed at the lower rear part of the helmet left and right relative to the helmet plane of symmetry 42 as it is shown at FIG. 3 A, section A-A. Since the micro display 4 and the microprocessor 3 are being heated while operating, they are provided with the radiators 43 and 44, carried out of pure aluminum with the best thermal conductivity per unit of mass. The radiator 43 is fixed on the upper outer area of the helmet by use of screws or glue and connected with the micro display 4 by use of flexible thermally conductive material. The radiator 44 is fixed on the rear outer area of the helmet by use of screws or glue, as shown at FIG. 3B, section B-B, and connected with the microprocessor 3 by use of the same flexible thermally conductive material. The radiators 43 and 44 collect the heat from the micro display 4 and microprocessor 3 respectively and disperse it into the surrounding atmosphere by blowing the helmet with an air stream when the motorcycle is moving.

Advantages of the Invention

[0051] Ensuring safe motorcycle riding is still a relevant problem currently. Accordingly, there is a need to search and develop new technical and technological solutions. Growing popularity of high-speed motorcycles of medium and high power and soaring traffic cause an increase in crash rates among the motorcyclists. Another reason is the lack of awareness of the motorcyclist in a changing real traffic situation, especially when maneuvering. In this case a dangerous situation occurs because visual contact with the road is being interrupted. The same situation occurs when the motorcyclist is taking readings from the speedometer or the fuel sensor, which are located on the dashboard. Since the proposed helmet-mounted display system provide the motorcyclist with more complete information about the current real traffic situation he does not need to turn his head towards the side rear-view mirrors or interrupt visual contacting with a front view area while taking readings from the speedometer or fuel sensor, etc. Moreover, in such cases there is no problem of re-accommodation and re-adaptation of the motorcyclist's visual apparatus. Thus, the application of the proposed helmet-mounted display system helps to improve driving safety and reduce accidents involving the motorcyclists.

[0052] To implement the suggested helmet, equipped with the collimating display system, the most rational design scheme has been developed, given that the inclusion of any additional elements in the design of the helmet leads to an increase in its weight and dimensions causing inconveniences for a helmet wearer and increase of production costs. Unlike the helmet by U.S. Pat. No. 10,098,401B2 the proposed helmet design does not include:

[0053] rear view TV camera with appropriate fixing elements and device for stabilizing its' spatial position;

[0054] air turbine and located in the helmet upper part special air channel with located in it a turbo-generator, intended to recharge the accumulator battery, which is switchable to fan mode to cool the accumulator battery and also the driver/s head in hot weather;

[0055] signaling elements located on the helmet housing, since using the proposed collimating display system the required signaling information is displayed directly in front field of view of the motorcyclist.

[0056] Thus, no one of the above listed features is not present in the proposed helmet-mounted display system. It was noted above that according to the statement of the authors of the patent U.S. Pat. No. 10,098,401 the helmet by said patent is not a HUD. whereas the proposed helmet-mounted display system is based precisely on principles of the HUD build-up being adapted to the specifics of driving a motorcycle. At the same time it should be noted that the helmet has a special device designed to ensure safety of the motorcyclist when putting on or removing the helmet, as well as to avoid damage to internal equipment of the helmet itself. The system according to U.S. Pat. No. 10,098,401 patent lacks such important components available in the proposed system as a camera and a photo sensor, measuring the external background brightness, significantly expanding the capabilities of the proposed system by providing full photo and video recording of current events, as well as performing automatic brightness control to achieve a comfortable image contrast. Some of the listed criticisms also relate to the helmet by the U.S. Pat. No. 10,182,606 patent. Some important aspects are not taken into account in said patent, e.g., such as the following: what is the technical solution of the design used to ensure the wearer's safety when putting on and removing the helmet. In addition:

[0057] the frame construction, proposed in the patent for attaching the monocular display to the helmet, will significantly worsen the view of the external space, inevitably causing decreased safety both for the helmet wearer and for the surrounding participants of traffic;

[0058] the helmet by said patent, connected with the on-board devices and power supply by the cable, practically cannot be applied for the motorcycle driving for basic safety reasons because under accidentally falling from the motorcycle, even with not high speed driving, the driver, “fastened” to the motorcycle by the cable, can get a severely injury to the cervical spine with loss of consciousness and even fatal.

[0059] Cooling of the heat emitting devices is carried out by use of the radiators. In nearest future due to the transition to a higher-level 7 nm chip integration technology the power consumption and heat emission will decrease significantly and that will improve thermal conditions inside the helmet. Charging of the battery located in the helmet is carried out from the charging device, e.g., by Pi standard type, from the motorcycle power supply Due to significant progress in the field of electronics, the prerequisites are created for increasing the range of the charger.

[0060] Being the most affordable and wide applied component the TV camera is used in the proposed system to provide the rear hemisphere view and located on the motorcycle body. At the same time in some cases special purpose motorcycles must be equipped with a viewing system with night vision option. In this case it is necessary to use a low-level TV system instead of conventional TV camera or introduce a special night vision channel in addition to the TV camera. In above case it is practically impossible to mount such systems directly on the helmet.

[0061] In the proposed system to avoid blinding the motorcyclist due to high ambient light the helmet is equipped with a movable visor similar to available ones and made of organic glass of neutral color with specified transparency coefficient. A similar visor can be made of transparent organic glass with a photochromic coating, which automatically adjusts the light transmission from the external space.

[0062] The proposed system can be used for other human controlled vehicles of various purposes.