RU118140U1 - PERSONAL ELECTRONIC COMMUNICATOR - Google Patents

Abstract

1. Personal electronic communicator containing a housing with right, left and end sides, on which a touchscreen display made of touch glass with built-in backlight LEDs is located over the entire surface of the housing, and under it there are left and right video cameras sensitive in the visible and infrared ranges, connected with an image processing processor interacting with a central processor, to which a memory unit and a program unit, microphones, loudspeakers, communication means of wireless personal networks and a battery with a charger are connected, the program unit is equipped with a control module via a touchscreen display and means at least one user interface without tactile input to the display. ! 2. The communicator according to claim 1, characterized in that the body is made impenetrable, in the form of a rectangular parallelepiped with cut edges, with continuous surfaces of the sides equipped with infrared illumination diodes. ! 3. A communicator according to any one of claims 1 and 2, characterized in that all built-in information exchange devices, including video cameras, microphones, loudspeakers and means of communication of wireless personal networks are duplicated on the front and back sides of the case under a layer of touch glass, while microphones and loudspeakers made of piezoceramic are placed in four corners of the body. ! 4. The communicator according to claim 3, characterized in that the video cameras and the user interface, operating without tactile influence on the display, are made with the ability to fix the position of the user's gaze along the pupil and

Description

The invention relates to mobile electronic equipment, in particular, to personal electronic communication devices with a touch panel, a display as input devices for transmitting data to be converted into a form suitable for processing, and communication devices including a touch screen (hereinafter referred to as a smartphone) future or SPF - Smart Phone Future).

A mobile communication device comprising a touch screen is known. It is possible to display a plurality of elements, receive a first sensor signal indicating that an element having a position on the screen has been selected, receive a second sensor signal and scroll through a portion of the displayed elements other than the selected element, while the selected element remains fixed in its original position on touch screen, in response to the second touch signal (RU No. 2402179).

A mobile terminal is known, which comprises a housing having a partition board dividing the housing into front and rear sides. The rear side has a first receiving location and a second receiving location located along the length of the housing. The front cover is located so as to at least / partially cover the surface of the front side of the housing, and has a transparent part that forms the window of the display device. The display device is mounted in the space between the front cover and the front side of the housing. The touch screen is located between the front cover and the display device and provides signal transmission when you touch the transparent part. A pair of guide substrates of the electrical circuit is located in the first receiving location. The camera is located in the first place of reception. The battery is located in the second receiving location, and the back cover is located so as to at least partially close each of the first and second receiving locations (RU No. 2385533).

A known mobile phone comprising a housing, a front opening cover, displays, the first of which is located on the outside of the cover, the second on its inner side, the third on the front side of the housing and closed by a cover, and the fourth on the front side of the housing, lower than the closed cover, that the first and fourth displays are facing the user and are active with the lid closed, and with the lid open, the second, third and fourth displays are facing the user and are active, built-in printed circuit boards carrying electronic components, phot o / camcorder, flash lamp and antenna located on the rear side of the upper part of the case, three microphones and five speakers, a battery made in the form of a removable back panel of the case, an interface for connecting a charger and a headset, three contact slots for two SIM cards and a memory card equipped with swivel covers, an infrared port, side volume keys and on / off cameras / camcorders, FM radio, MP3 player and voice recorder. The first display is configured to be converted into a touch control panel with a keyboard, the second and fourth displays serve to visualize information, and the third is a touch control panel with a keyboard (RU No. 2373661).

A mobile terminal is known, combining a mobile phone and a laptop, consisting of four fragments articulated on the long sides, made with the ability to fold and unfold two fragments of the case into the display of the "laptop" and two more fragments of the case into the keyboard of the laptop, and then has the ability add up already folded fragments into one case, and one of the planes of a single case will be the top panel of the phone. The display and keyboard of the “laptop” that are foldable in pairs are touch panels, and the top panel of the “mobile phone” is a touch panel that can be transformed from half of the display or keyboard (RU No. 83630).

The disadvantages of these devices is the limited functionality for interacting with the user, the complexity of management.

Known electronic device with a touch panel, display and joystick, in which at least one touch panel, or at least one part (sector) of the touch panel, or at least one joystick, or part thereof is placed on the back of the housing of the electronic device for functioning in the specified position, while the user of the electronic device through manipulation with the touch panel, or its part (sector), or with the joystick, or part of it controls at least one virtual symbol, from On at least one display located on the front side of the housing of the electronic device, either the touch panel, or part of it (sector), or the joystick is partially placed on the back of the housing of the electronic device, or the touch panel or part of it (sector) is simultaneously placed on the side and the reverse sides of the housing of the electronic device, while the touch panel has at least one bend, or the touch panel or its part (sector) is placed simultaneously on the front, side and back of the case an electronic device, or a touch panel, or a part thereof (sector), or a joystick, is configured to move it (him) along the body of the electronic device, or at least one sector is created on the touch panel, or part thereof, or on the touch screen, by which control at least one virtual symbol displayed on at least one display located on the front side of the housing of the electronic device. The touch panel or its part (sector) has a fully or partially convex shape, or the touch panel, or its part (sector), or the joystick has a protective cover, or c) the touch panel, or its part (sector), or the joystick replaces the protective the lens cap of the camera or camcorder or is located on the protective lens cap of the camera or camcorder. The display is placed on at least three sides of the housing of the electronic device, namely on two opposite sides and at least one side, the display is fully or partially touch-sensitive, while at least one virtual symbol displayed on the indicated display is controlled by actions with the touch part of the display (RU No. 2427879, prototype).

The disadvantage of the prototype is the limited functionality in terms of how to interact with the user and remote switching, the limited possibilities of operational use at any position of the communicator in the hand, the need to use both hands to work with the communicator, low reliability associated with the possibility of undocking the case and low durability, determined by the presence replaceable elements.

The technical task of the utility model is to create an effective personal electronic communicator and expand the arsenal of personal electronic communicators.

The technical result is to expand the functionality of the electronic communicator in terms of providing non-tactile (without mechanical contact) interaction with the user and remote switching to control virtual characters displayed on the touch screen, as well as expanding the possibilities of operational use at any position of the device in the hand with use, when need, only one hand to work with the communicator, increased reliability associated with a jointless dust and moisture protected housing design and increased durability, determined by the absence of replaceable elements, as well as increased efficiency.

The essence of the utility model is that a personal electronic communicator contains a case with right, left and end sides, on which a touch screen made of touch glass with integrated backlight LEDs is located on the entire surface of the case, and under it are the left and right cameras, which are sensitive in the visible and infrared ranges associated with an image processor interacting with a central processor to which a memory unit and a program unit, microphones, loudspeakers, means are connected communication of wireless personal networks and a battery with a charger, the program unit being provided with a control module by means of a touch display and means of at least one user interface operating without a tactile effect on the display.

Preferably, the housing is made impermeable, in the form of a rectangular parallelepiped with cut ribs, with the jointless surfaces of the sides equipped with infrared backlight diodes.

Preferably, all the built-in information exchange devices, including video cameras, microphones, loudspeakers and wireless personal communication devices, are duplicated on the front and rear sides of the case under a layer of touch glass, while microphones and piezoceramic loudspeakers are placed at the four corners of the case.

In special cases, the implementation of the communicator of the camera and the user interface means, acting without tactile influence on the display, are made with the ability to fix the position of the user's gaze on the pupil and the time it was fixed on the virtual keyboard, as well as maintaining accumulative statistics about user actions.

In other special cases, the implementation of the communicator of the camcorder is equipped with additional lines of sensitive pixels in the infrared range of 1-5 μm, and the user interface means, acting without tactile action on the display, are made with the ability to fix the position of the object moved by the user over the display, as well as maintaining accumulative statistics about actions user.

In other special cases, the communicator’s implementation of the camcorder is equipped with additional lines of sensitive pixels in the infrared range of 1-5 μm, and the user interface means, acting without tactile action on the display, are made with the ability to fix the user's gaze position on the pupil and the time it was fixed on the virtual keyboard, and the ability to fix the position of the item moved by the user above the display, as well as maintaining accumulative statistics about user actions.

Preferably, the communicator is equipped with a built-in recorder of environmental hazards, for example, a radiation detector, as well as a built-in spatial orientation device, such as an accelerometer or gyroscope.

The battery is made on the basis of graphene components, and the charger is made inductive or photoelectric.

Preferably, the means of wireless personal networks communication is made with remote switching modules with external devices using Bluetooth and NFC (Near Field Communication), and with at least one device of its owner for making a decision on allowing / denying access according to the Svoi-Alien principle .

The drawing shows a block diagram of a personal electronic communicator, for example, a smartphone, laptop, tablet, terminal, etc. personal electronic device.

In the drawing are indicated:

1. The case (conditionally indicated) of the SPF communicator - a smartphone, laptop, tablet, terminal, etc. personal electronic device

2. High-definition camcorder (left)

3. Multifunctional touch display (over the entire surface of the housing 1).

4. High Definition Camcorder (Right)

5. Image processor

6. memory module

7. Central processor

8. Power controller

9. Interface module

10 Battery

11 Photovoltaic Battery Charger

12 Inductive charger

13 The GSM / 3G / UMTS module is designed for high-speed data transmission in GSM and G3 networks, using the GPRS / EDGE and UMTS / HSPDA protocols with a speed of up to 7.2 Mbps.

14 Bluetooth module (wireless personal area network specification)

15 Wi-Fi module (for wireless networks based on the IEEE 802.11 standard)

16 Navigation module (GPS / GLONASS)

17 NFC module (near field communication).

The central processor 7 implements its usual functions, as in any smartphone. The image processing system includes video cameras 2.4, a translucent multifunctional touch display 3, an image processing processor 5. Multifunction display 3 is designed to display all the visual information of the smartphone. It has built-in elements (not shown) of infrared illumination and light illumination, housed in the display 3. The power controller 8 selects and controls the battery 10 and chargers 11, 12.

The charger can be made in the form of a photovoltaic device (converter) 11. The charger can also be made in the form of an inductive device 12 with inductive coupling supplied with a high-frequency current. Induction coils of such a device 12 can be made in the form of planar spiral coils.

Interface module 9 is a controller and hardware of all available interfaces 13-17 and others.

The Communicator (SPF) has a jointless impermeable (monolithic) housing 1 without any adapters, contacts, joints, holes and joints (i.e. dust and water tight). The housing 1 and its elements, lateral borders and ends are made in the form of slices of the processed crystal. The entire surface of the housing 1 is made with a translucent (colored) outer layer of thin transparent plastic or glassy polymer with an absolutely smooth, sparkling polished surface. According to the visual solution of the color, the housing 1 may be a deep greenish color. In this case, the SPF will be more like a flat, rectangular, sawn crystal, for example, the Ural emerald. The new touch-sensitive personal communicator (SPF smartphone) stands out with its unique and original shape. It creates an optical sensation that the entire smartphone case is carved from a crystal of the Ural emerald and polished to a mirror shine. The end surfaces of the SPF case have strict, even edges that enhance the effect of a single, monolithic crystalline body that attracts the eye and palm of your hand. The multilayered surface structure of the SPF and the material from which this device is made is shocking in its high technology and undoubtedly ahead of its time. Strength, high definition stereoscopic image, something that we could not believe in before - became possible. A phone that can be operated at a glance without touching (Vi-TO - Virtual Touch Screen) is also equipped with a virtual contact system (Vi-Co - Visual Contact) this is no longer fiction.

In the future, it is possible to make it any color to order, including black.

The absence of negative characteristics - such as difficult use in various adverse weather conditions, and even under water, which is common among touch phones. SPF is a new reality. Reality where anything is possible.

The entire surface of the housing 1 with the outer layer of thin transparent plastic or glassy polymer is a solid durable touch screen 3 with electrodes of 2-3 layers of graphene. Graphene can be equipped with valves to protect and strengthen the housing 1. Touch screen 3 - information input device, which is a screen that responds to touch. The on / off button and the sound / vibration switch may represent certain places on the housing 1.

Currently obtained suitable for the manufacture of display 3 rectangular sheet of graphene with a diagonal of 76 centimeters. Graphene is doped with nitric acid, as a result of which it has the ability to act as a large transparent electrode when this electrode is embedded in the touch display 3. The graphene electrode is more transparent and more durable than its tin-indium analogues. The graphene-based touch displays 3 have a long service life, the production of graphene-based displays requires a relatively small amount of carbon and additional materials, rare metals are not needed, the copper substrate can be used an unlimited number of times, see http://m-protect.ru /index.php?id=1177&option=com_content&task=view;

http://ru.wikipedia.org/wiki/%C3%F0%E0%F4%E5%ED).

When tactile (mechanical) touching the outer layer made of thin transparent plastic, i.e. display 3, its inner conductive surface is combined with the conductive layer of the main glass plate, which plays the role of the frame structure, due to which there is a change in the resistance of the entire system. This change is recorded by the processor 7, which determines the coordinates of the touch point. When using graphene electrodes, it is also possible to implement a capacitive touch display 3.

The diagonal of the case 1 side (i.e. the diagonal of the touch screen) of the SPF should have an optimal size of 4.2-4.5 inches or 10.7-11.4 cm, up to 5 inches or 12.7 cm, i.e. in size larger than the iPhone 4,4s smartphone. The thickness of the housing 1 SPF can be only 7 mm. This is significantly less than the same iPhone 4,4s smartphone. This format of the housing 1 is convenient for a person with the girth of his entire palm. This is important for giving the SPF device the functions of a mobile tablet, and a tourist video screen. Given the trends in the technology of electrical elements for electronic devices, their sizes can approach the level of 5-10 nm. This will further reduce significantly the energy consumption of the SPF device, reduce the size of the battery 10 and the thickness of the housing 1.

In this case, the communicator housing 1 may resemble a translucent crystal, for example, of deep green color (other color options are possible). Both sides of the housing 1 duplicate each other with their functions, like the screens of the front and rear sides, and all built-in devices, in particular video cameras 2,4, microphones, loudspeakers are duplicated on each side of the housing 1.

Any external devices can be switched with the SPF communicator, for example, using module 14 Bluetooth (production specification of wireless personal networks). Bluetooth provides the exchange of communicator information with devices such as personal computers (desktop, handheld, laptops), mobile phones, printers, digital cameras, mice, keyboards, joysticks, headphones, headsets on a reliable, inexpensive, universally available radio frequency for short-distance communications. Bluetooth allows these devices to communicate with the device when they are within a radius of 1 to 200 meters from each other (depending on the presence of obstructions and interference), even in different rooms.

In addition, any external devices can be switched with the SPF communicator, for example, using module 17 Near Field Communication (NFC) - “near field communication” - short-range wireless high-frequency communication technology that enables the exchange of data between devices located on a distance of about 10 centimeters (about 4 inches). The NFC device can communicate with surrounding smart cards and readers of the ISO 14443 standard, and with other NFC devices, and thus is compatible with the existing contactless card infrastructure already used in public transport and payment systems. NFC is primarily intended for use in mobile phones and is suitable for communicating automatically over the protocol with any other device of its owner.

The intelligence and program logic of processor 7 includes a statistical analysis of the handling of the device of its immediate owner, automatic programmable communicativeness of Svo-Alien, the ability to use a universal, digital, radio frequency standard for data transfer, the ability to stereo and quad sound, and stereo vision, a fully surface touch screen 3 working in conjunction with a touchscreen sensor, with the addition of logic elements and individual options for visual contact and control, as well as Wirth touch touch.

The top and bottom of the SPF communicator are determined by the built-in spatial orientation device, in particular, an accelerometer or gyroscope, which is responsible for the position of the screen in modern smartphones. Piezoceramic loudspeakers and microphones are located on the four edges of the housing 1, for the inclusion and control of which there are elements of logic and intelligence. They turn on and work in the necessary mode when determining the position of case 1. As a result, when the owner (regular user) picks up his SPF communicator, for example, a smartphone, his processor 7 from the beginning determines the position of case 1, and then predicts the most likely actions of his master, based on accumulative statistics about his preferences and actions of his master.

The built-in recorder of environmental hazards will warn the owner, if necessary, of the presence of radioactive radiation and other hazards, for example, earthquakes, tsunamis, volcanic eruptions, tornadoes, etc., in which the electric or magnetic components of the fields and other measured physical parameters at the places of occurrence change environmental disasters.

The control function on the virtual keyboard of the display 3 can be performed by physical touch the index finger, or any other object resembling a finger, for example, a pencil, pen, etc.

Each user interface combines structural (circuit) elements and components of the program, which are able to influence the interaction of the user with process software 5.7. These items include:

- A set of user tasks that he solves using the system;

- system controls;

- navigation between system blocks;

- means of displaying information, displayed information;

- devices and technologies for data input;

- dialogs, interaction and transactions between the user and the processor 7;

- feedback from the user;

- decision support in a specific subject area;

The SPF communicator is equipped with fundamentally new user logical interfaces that act in addition to the tactile (mechanical) effect on the display: visual and virtual contact systems Vi-Co - Visual Contact (Visual Contact) and Vi-To - Virtual Touch Screen - Virtual contact or virtual touch touch screen 3, allowing to significantly simplify and diversify user interaction with the communicator. The built-in, high-contrast (high-definition) video cameras 2.4 are located symmetrically under the thin glassy layer of the touch screen 3 in its opposite sides. Used high-resolution 2.4 cameras with dynamic stabilization operating in the visible and infrared range. In addition to LED RGB rulers, they also contain infrared sensitive pixel lines.

The infrared (IR) pixels of the 2.4 video cameras are capable of sensing light in a narrow spectral range, it is possible to adjust the focus area. The device is equipped with diodes for infrared illumination of the display 3.

Video cameras 2.4 and LEDs of visible light illumination should be located on display 3 so as to provide high-quality illumination without glare and shadows. At the same time, the LEDs should not blind the 2.4 cameras.

Video cameras 2.4 are universal, located on both sides of the case 1 of them in 2 pieces. This is done to unify the properties of both sides of the housing 1, to provide additional two-screen functionality of the device and the same ease of use with the right and left hand. If the case 1 is taken with the right hand, then the part that is free from the girth of the palm of the hand and will be the working surface of the display 3. Thanks to the 2.4 cameras and the productive processor 5, the latter can calculate the user's gaze position from the position of the pupil and its fixation time on the virtual keyboard display 3. As a result, you can implement the touchscreen function without a tactile (physical or mechanical) touch of the display 3.

Icons of various programs and functions, a virtual keyboard with its alphabetic, digital and symbolic designations will be a virtual target for gaze, point of view. As a result, further control can be carried out from visual contact.

With visual contact (as if touching) - looking at a specific point on the touch screen 3, the signal is processed programmatically for processor 5, similar to the electrical circuit of the conductive layers at this point on the SPF display.

Two symmetrically located high-resolution video cameras 2.4 monitor the space immediately in front of the display with dynamic stabilization and online tracking the dynamics of the movement of the pupils of the eyes along the edges of the housing 1 capture the image of the pupils of the user. To register the fixation points with video cameras 2,4, for example, an invisible beam of infrared light can be emitted, which is reflected from the user's eyes, and the brightness of the reflected signal from the pupil and iris is different. At a sampling frequency of 120 Hz, every 8.3 ms of the 2.4 video camera generates an image, and with it, a signal of a certain structure is reflected from the eyes. The direction of gaze is set using a vector, which is determined based on the difference between the signals reflected from the pupil and the iris. Next, the received reflected signals from two video cameras 2.4 are processed by the image processing processor 5. Using a special program, the image of the pupil is recognized and its initial position is determined for both 2.4 video cameras. The linear and angular movement of the pupils, the fixation of the point of view is calculated according to the results of processing images from 2.4 video cameras using correlation methods to increase the accuracy of determining the position of the pupils. The image processing processor 5 filters out a large number of eye movements and blinks in order to calculate fixation points, i.e., the areas really perceived by the pupils of the user, and provides additional image correction and stabilization. After calculating the coordinates of the pupils, the data of the processor 5 of the image processing are sent to the main processor 7 of the device to execute the subsequent program code (virtual visual contact).

Each 2.4 camcorder receives signals from both pupils. Video cameras 2.4 are made with the possibility of mutual cross-control of the position of the point of view. The coordinates of the visual touch point are calculated programmatically by the processor 5, using the angular and linear movements of the pupils of the user relative to the touch display 3. This allows you to clearly determine the coordinates of the pupils of the human eyes, therefore, to make more subtle ways to control the virtual cursor on the touch display 3 and develop a greater speed of visual print control , working with SMS messages, working with files and surfing the Internet. The image processing processor 5 processes the signal from the video cameras 2,4 using a specialized program for multifactor control of brightness, clarity, detail, noise suppression, signal saturation, visual balance control of objects of analysis and control (pupils) and other signal parameters, for example, eye blink frequency, vibration of the housing 1 in the hands, glare and light levels, etc.

To implement this technology, Vi-Co should hold your eyes, for example, at 0.25-0.5 seconds. on the desired virtual keyboard key on the display 3. To really develop this skill to full perfection, that is, up to 480 or more characters per minute. In the future, the processor 5 will adjust itself to the user and fix the optimal speed of visual gaze control based on the Vi-Co skills development program.

Visually typed text can also be edited. To do this, the user needs to hold his eyes on the “wrong” letter, for example, for 0.75 seconds. in the word 3 already written on the display. In order to make another correct letter in a given corrected word from the virtual keyboard, it is necessary to “glue” it with a glance to transfer the visually corrected word to the right place.

Video cameras 2.4 can be implemented each in the form of a small-sized video camera that tracks the movements of the pupils and converts the received information into commands that are understandable to the operating system and all installed programs (Senseye technology).

An example of working with fixing the position of the user's gaze on the pupil on the virtual keyboard of Vi-Co (Visual Contact):

The user needs to type an SMS message. We focus on the SMS icon area, hold it for 0.25 seconds. This opens the editor with a virtual keyboard. The text is typed by focusing the gaze in the region of the required letter key and delaying it for 0.25 seconds. After which it is virtually pressed (Virtual Contact) and the desired character is displayed in the SMS editor. In order to select the necessary part of the tex, you need to focus your eyes at the beginning of the desired section of the text and hold it for 0.5 seconds. A virtual cursor and the virtual keys “Copy”, “Paste”, “Delete” will appear. When the gaze moves in the right direction, the desired piece of text will be highlighted. The completion of the visual copying process is fixed by a delay of a glance of 0.5 sec. at the end of the copied text. Then the selected text is processed on the basis of virtually pressed keys (Virtual Contact) "Copy", "Paste", "Delete".

In the same way, navigation through the menu of the SPF communicator is performed. To launch the necessary application, it is enough to focus your eyes on the “icons” needed to launch the application and hold your eyes for 0.25 seconds.

To implement the virtual touch function, i.e. non-tactile (without mechanical interaction) fixing the position of an object moved by the user above the display (Vi-To), video cameras 2.4 are equipped with additional lines of sensitive pixels in the infrared range of 1-5 microns. The illumination of a moving object - for example, a finger or a stylus is carried out in this range with the help of LEDs built into the display. The LED radiation scattered by a finger is recorded by 2.4 video cameras. It turns out the image as in a regular black and white camera. This ensures a virtual touch mode in which every movement of a finger or other pointing object (stylus) is tracked relative to the display 3 without direct mechanical (physical) contact with the surface of the display 3. These movements are converted into commands that are understandable to the operating system and all installed programs (technology Senseye). When implementing the function of a virtual touchscreen (Vi-To), the image processing processor 5 recognizes an object that performs the function of a stylus. Recognition of the image is the same as in the case of the pupils. The focus area of cameras 2.4 is shifted closer to the display 3. The backlight area is shifted to the same area. To determine the coordinates of the finger (stylus) and its movement, the same methods are used as in the Vi-Co visual contact system. Pressing is modeled by quickly moving the stylus in the direction of the display 3. In the case of touching the display 3, the pressing signal is duplicated by the signal of the touch display 3.

An example of the Vi-To (Virtual Touch) system:

You need to dial an SMS message. We bring a finger or stylus to the area of the SMS icon, perform a natural movement of pressing quickly enough, an editor opens with a virtual keyboard for display 3, and touching the display 3 is not necessary. At the moment of the reverse finger movement, a virtual keystroke takes place and the symbol we need is displayed in the SMS editor. In order to select the necessary part of the text, you need to perform the movement of pressing towards the display 3 and fix the finger at the beginning of the text segment we need without performing the reverse movement. A virtual cursor and the virtual keys “Copy”, “Paste”, “Delete” will appear. When you move your finger in the direction we need, it will highlight the desired piece of text. The completion of the copying process is fixed by the usual movement of clicking on the end of the copied text. Then the selected text is processed on the basis of virtually pressed keys (Virtual Contact) "Copy", "Paste", "Delete".

Navigating the display 3 menu is done in the same way. For most users, the display 3’s own backlight is enough when working in the dark to position the look in letters and texts.

The touchscreen operation with mechanical (physical) touch of the virtual keyboard on the display 3 is saved as a duplicate function and is intended for visually impaired and in complete darkness, where it is difficult to identify the position of the pupils of the eyes.

The battery 10 is able to be charged, for example, inductively from a special stand that acts as a charger. Under the surface of the display 3 of the housing 1 can be installed photovoltaic converters 11, which, if necessary, perform the functions of a battery charger 10. When the expected efficiency> 50% and normal illumination, they cover the device's electricity needs.

The battery 10 (battery battery) is preferably made on the basis of graphene components, and therefore is able to maintain a long-term charge, possibly up to 1 month without recharging in silent mode. Such a battery 10 will have a significant service life with a "limitless" number of charge-discharge cycles. Therefore, it is packed in a one-piece housing 1, as if in a crystal, forever.

Piezoceramic loudspeakers on the four edges of the body will complement the functionality of the device, while creating both stereo and quad sound. Four microphones are also located on the edges of each side of the housing 1, designed to more clearly recognize the speech of the owner of the smartphone and control the smartphone with voice commands, as is the case with the search technology in Siri smartphones for the Internet.

Symmetrically located high-resolution video cameras 2.4 on the sides of the housing 1 can provide a stereo signal for the subscriber at the opposite “end of the wire” in the video call mode, display 3 provides stereo vision.

The microphones and speakers in the inventive communicator SPF are expediently based on silicon technology; for such devices, open contact with sound and voice is not needed. They are able to transmit high-quality sound and, if necessary, to recognize voices, thanks to built-in broadband amplifiers. Means for changing the magnitude of the sound, turning it on and off, as well as means for implementing other control operations can be traditionally placed, for example, at the ends of the housing 1 of the smartphone. The control program for processor 7 is equipped with logic and intelligence elements, and processor 7, as it were, foresees the actions of a regular user based on accumulative statistics of the treatment of its owner.

The evolution of speech recognition and processing programs and the powerful integrated processor 7 make the communicator an effective translator. With it, people of different languages can communicate with each other without resorting to the services of translators when talking through the claimed SPF communicator.

Thus, the inventive communicator, for example, a smartphone, can be involved in the following modes.

When turned on, the user is prompted to select a smartphone control mode:

A.) Touch control of the smartphone (control of the smartphone using the touchscreen). When mode A is selected, the smartphone boots in the mode of a regular touchscreen smartphone with a tactile touchscreen control mode.

B.) Visual control of the smartphone (control in Visual Control or Vi-Co). When choosing mode B, the user should calibrate his smartphone to control it in the Vi-Co system for his type of eyes, the distance between the pupils, the dynamics of the movement of his gaze, etc. After calibration, the smartphone boots up under the control of the Vi-Co system and is completely controlled by the gaze. In this case, the user, focusing on the desired area of the display 3, delays the gaze for 0.25 seconds. As a result, there is a virtual press in this area of the display 3.

C.) Managing your smartphone using the system "virtual touchscreen" (contactless touchscreen) or Vi-To. When choosing mode B, the smartphone user should calibrate his smartphone to control the Vi-To system under his finger or the existing type of stylus. Moreover, in the function of the virtual touchscreen, the image processing processor 5 recognizes an object that performs the function of a stylus. It can be a finger, or any other object of suitable size. Recognition of the image is the same as in the case of the pupils. The focus area of the 2.4 cameras is shifted closer to the display 3. The backlight area is shifted to the same area. To determine the coordinates of the finger (stylus) and its movement, the same program methods are used as in the Vi-Co system. Pressing is modeled by quickly moving the stylus in the direction of the display 3. In the case of a tactile touch of the display 3, the pressing signal can be duplicated by the signal of a mechanical sensor (for example, an accelerometer, gyroscope or touch panel).

As a result of this technical solution, the functionality of the electronic communicator was expanded in terms of providing non-tactile (without mechanical contact) user interaction and remote switching to control the virtual symbols displayed on the touch screen, as well as expanding the possibilities of operational use at any position of the device in hand with using, if necessary, only one hand to work with the communicator, improving the reliability associated welded execution housing precluding penetration of water when submerged and increase durability defined pylevlagozaschischennym execution and the absence of replaceable elements, and increase efficiency.

Claims (11)

1. A personal electronic communicator comprising a case with right, left and end sides, on which a touch screen made of touch glass with integrated backlight LEDs is located on the entire surface of the case, and under it are left and right cameras, sensitive in the visible and infrared ranges, connected with an image processor interacting with the central processor, to which a memory block and a program block, microphones, loudspeakers, communication means of wireless personal networks are connected, and kumulyator with a charger, wherein the program unit is provided with a control unit by means of the touch screen and the at least one user interface, without the active tactile feedback on a display. 2. The communicator according to claim 1, characterized in that the housing is impermeable, in the form of a rectangular parallelepiped with cut ribs, with jointless surfaces of the sides equipped with infrared backlight diodes. 3. A communicator according to any one of claims 1 and 2, characterized in that all the built-in information exchange devices, including video cameras, microphones, speakers and communication means of wireless personal networks are duplicated on the front and rear sides of the case under a layer of touch glass, while microphones and piezoceramic loudspeakers are placed at the four corners of the housing. 4. The communicator according to claim 3, characterized in that the cameras and user interface tools that operate without a tactile effect on the display are made with the ability to fix the user's gaze position on the pupil and its fixation time on the virtual keyboard, as well as maintaining accumulative statistics about user actions . 5. The communicator according to claim 3, characterized in that the camcorders are equipped with additional lines of pixels that are sensitive in the infrared range of 1-5 μm, and the user interface means, acting without tactile action on the display, are configured to fix the position of the object that the user moves over the display , as well as maintaining accumulative statistics about user actions. 6. The communicator according to claim 3, characterized in that the cameras are equipped with additional lines of sensitive pixels in the infrared range of 1-5 μm, and the user interface means, acting without tactile action on the display, are configured to fix the user's gaze position on the pupil and its time fixing on the virtual keyboard and with the ability to fix the position of the item moved by the user above the display, as well as maintaining accumulative statistics about user actions. 7. The communicator according to any one of claims 1, 2, 4, 5, 6, characterized in that it is equipped with a built-in registrar of environmental hazards, such as a radiation detector. 8. The communicator according to any one of claims 1, 2, 4, 5, 6, characterized in that it is equipped with a built-in spatial orientation device, such as an accelerometer or gyroscope. 9. The communicator according to any one of claims 1, 2, 4, 5, 6, characterized in that the battery is based on graphene components. 10. The communicator according to any one of claims 1, 2, 4, 5, 6, characterized in that the charger is made inductive or photoelectric. 11. A communicator according to any one of claims 1, 2, 4, 5, 6, characterized in that the means of communication of wireless personal networks are made with remote switching modules with external devices using Bluetooth and NFC (Near Field Communication) and with at least at least one device of its owner for making a decision on permission / prohibition of access on the basis of the Self-Alien principle.