UA119846C2 - MULTIPURPOSE MODULAR MOBILE ELECTRONIC DEVICE WITH VARIABLE CONFIGURATION AND FUNCTIONALITY - Google Patents

Abstract

The invention relates to universal electronic mobile devices for receiving, processing, storing, transmitting and displaying information in digital format, which are used to meet the various needs of users. Multi-purpose modular mobile electronic device with variable configuration and functionality, comprising: functional block modules configured to transmit information and electrical signals to receive, store, process, transmit and display information, a housing formed by a combination of a back cover on which are placed functional block modules, and the top cover, which is the main screen, while the housing does not necessarily have a touch screen on the side surface, and its shape and overall design determine the model of the device; means for opening / closing the housing, while the functional block modules contain a subplate, magnetic means of fixing the functional block modules.

Description

The invention belongs to universal electronic mobile devices designed for reception, processing, storage, transmission and display of information in digital format, which are used to meet various user needs.

A wide range of electronic devices used to work with multimedia files is now known, including audio recordings, for creating and viewing photos, for working with various devices, other software, for telephone communication and support for various forms and communication protocols, etc.

In general, these devices are made so compact and mobile that the user, if necessary, can constantly carry several such devices with him. In particular, such devices can be mobile phones, tr3-players, tablet computers, etc.

With the advent of mobile phones, there has been a trend to make such devices more versatile and multi-purpose. Currently, this allows to reduce the number of devices intended for constant wear by the user and contributes to the expansion of his capabilities to satisfy certain needs. Yes, many mobile phones, in addition to the obvious communication function, can also take pictures of any objects, access the Internet, and perform additional functions, such as: listening to music, reading e-books, watching movies, playing electronic games games and so on.

The result of progress in this field is the appearance of modern multifunctional electronic mobile devices, so-called smartphones.

Such devices contain such basic elements as: a case, a printed circuit board and hardware elements placed directly on the printed circuit board or connected to the printed circuit board. The hardware elements include both separate electronic parts and technical elements mounted directly on the surface of the printed circuit board base, for example, a processor chip, and made in the form of separate modules - additional printed circuit boards, separated from the printed circuit board base, but in one way or another connected to the base of the printed circuit board.

The following examples of multifunctional electronic mobile devices are known from the existing state of the art.

Yes, there is a known application for a patent for an invention under the name REVB5OMAI O5IITAI. ABB5I5BTAMT, UR 2003039043820031120, IPC index NOYA4M 1/02, NO4M 1/00, submitted for registration on November 20, 2003

From the year, the applicant - Rapazopis Mobie Soott So, (I, MTT SORSOMO, Ips. publ. 16.06.2005, publication number 2005159399 (А), which disclosed a device containing a housing, two basic modules located in the housing, which with interconnected, and additional block modules. Basic modules contain printed circuit boards, on the front side of which a display element and a keyboard element are located, respectively, on the reverse side of the printed circuit boards there are contacts for connecting block modules. Block modules can be designed to perform various functions and have cases in the form of parallelepipeds, which allows you to compactly place block modules on the surface of printed circuit boards and rationally use the internal volume of the case. there is an electrical connection between the block modules and the exchange of electrical signals between them. Such a constructive solution of the device has obvious positive qualities, namely: allows you to easily change the functionality of the device, if necessary, remove or add block modules, replace those that have become "morally obsolete" with more modern ones. That is, thanks to the above-described functional capabilities of the device, it acquired such a property as variable functionality.

As one embodiment of such a digital electronic mobile device with changeable functionality, the document describes a mobile phone in which functionality can be changed. This mobile phone has such block modules as a processor block, a memory block, a power supply block, a display block, a keyboard block, a block for receiving and transmitting radio frequency signals and a block for converting acoustic signals into electrical signals and electrical signals into acoustic signals. The disadvantages of such a digital electronic mobile device are: - the lack of an opportunity to reduce the dimensions, mass and appearance of the device in the case when only a small number of block modules are needed, due to the fact that the dimensions of the device body are limited by the dimensions of printed circuit boards; - the impossibility of further expanding the functionality of the device and connecting new block modules in the event that all available contacts are occupied due to the fact that the size of the device and the number of block modules are limited by the number of contacts on the basic printed circuit board. - lack of possibility to replace all block modules with other block modules due to the fact that the specified device must necessarily have a screen or a keyboard element on the reverse side of the printed circuit board;

- low reliability of the device, which is due to the presence of a printed circuit board, which needs to be replaced in the event of a fall, penetration by solid objects, a strong impact, pressure on the surface of the device body; - the need, in the case of connecting a significant number of block modules, to make a printed circuit board with a significant number of contacts, which, in turn, significantly increases the size of the printed circuit board and increases the probability of the device failing due to the ingress of moisture, dust or small loose substances inside the case, on contacts and hardware elements placed directly on the printed circuit board, and damage to the printed circuit board, which, in turn, requires the creation of a case for such a device with a higher level of tightness than that of conventional devices and with larger external dimensions; - due to the fact that all block modules are connected to the printed circuit board and have a constant power consumption, in the case of a significant number of block modules, even in their inactive state, such a device will have a high level of power consumption.

The closest analogue of the claimed device, which was selected as a prototype, is the US application for a patent for the invention О52004/0100776 A1, entitled ROVTAVI E MOOISHI AV

EGESTAOMIS 5U5TEM, which was submitted for registration on November 27, 2002, inventors - M/iShat

A. Naav, Roy Soiyipv, So (05), Kiik 5. Tesy, Steyivu, So (05), publ. 27.05.2004, applicant NeulLei-

Raskagi Sotrapu), which discloses a digital electronic mobile device containing a memory module, a controller module and an application module. The specified modules, according to the invention, should be aligned along the axis and made with the possibility of mechanical connection with each other. The transmission of electrical signals between the blocks is carried out thanks to the bus and wire transmission, while the termination of the signal transmission occurs when the blocks are mechanically disconnected. The claimed device additionally contains mechanical connecting elements, while it is made with the possibility of turning the modules relative to each other by means of a mechanical connection.

The disadvantages of such a digital electronic mobile device are the following: - the set number of modules complicates the process of manufacturing and initial assembly, and also leads to an increase in the price of the device, especially in its maximum configurations; - the location of the memory modules, the controller module and the application module along the axis complicates the processes of both initial assembly and subsequent additions, replacements and removals, which, in turn,

This complicates the possibility of dynamic setting (configuration) of the device in accordance with the current wishes of the user; - the presence of mechanical connecting elements leads to unwanted costs for components, complicates the manufacturing and assembly processes, as well as subsequent additions, replacements and removals of modules. As you know, the mechanical method of connection contains numerous disadvantages, the main one of which is that such a connection of blocks to each other can lead to the breakdown of physical fastening elements and malfunction of the device as a whole, especially in case of mechanical damage, falling, etc. At the same time, any exchange of information signals and power between units cannot be automatically resumed after its termination. Also, with this method of connection, the mechanical contacts of the blocks may fail over time, which will lead to permanent breaking of the contacts between the blocks; - the functions of the device's screen can be performed by one of the standard blocks, so the size of such a screen will not allow the device to be really used with complex graphic applications, such as computer games, specialized programs for creating and processing graphic images, photos and video materials; - the specified device ensures the operation of only MRZ audio players, digital cameras and video cameras, digital voice recorders, PDAs, as well as portable data storage devices; - exclusively wired, contact method of information transfer and power supply between block modules limits certain possibilities of the user to use the device anywhere.

The problem to be solved by this invention is: - improvement of the technical and technological solution when building the design of the device body and creating such a scalable grid of sizes and proportions for placing functional block modules (hereinafter - functional block modules or block modules) ; - improvement of the technical and technological solution for the construction of functional block modules, their layout inside the device case, taking into account the possibility of placement from outside the case and determining the configuration of the device with the minimum number of functional block modules; - improvement of the system of fixation and fastening of functional block modules based on magnetic and electromagnetic elements and nodes;

- improvement of the scheme of transmission of power and information signals by means of direct contacts of functional block modules with each other without the use of a single printed circuit board and a common bus; - predicting the process of transmitting power and information signals inside the case between functional block modules wirelessly using a high-speed standard for transmitting information signals via radio channels (for example, MUUi-Ri), as well as acoustic, induction, and optical channels; - creation of prerequisites for the use of the most advanced technological solutions, also in the near future, without the need for any processing of the basic technical solutions according to the invention.

Also, the task of the invention is to solve the problem of creating a specific and maximally complete list of basic, additional and auxiliary functions and, thus, hardware included in the functional block modules.

The task is solved by creating a multi-purpose modular mobile electronic device with variable configuration and functionality, which is intended, including, but not limited to, for receiving, storing, processing, transmitting and displaying information.

In one of the non-limiting variants of the implementation of the invention, a multi-purpose modular mobile electronic device with variable configuration and functionality (hereinafter - the device) containing functional block modules, made with the possibility of transmitting information and electrical signals for receiving, storing, processing, transmitting and displaying information, according to the invention contains: - the case, which is formed due to the combination of the back cover, which is a functional element of the device, which is made with the possibility of fixation due to the magnetic connection inside the case of the functional block modules and - the upper cover, behind which the main screen protrudes, one side which is the main element of entering and displaying information and, optionally, the other side is the substrate-basis for placing functional block modules; while the body, optionally, on the side surface

Zo has a touch screen, and its shape and general design determine the device model, - means for opening/closing the case, optional, such as guides for shifting the top cover relative to the back when opening and closing the case, such as micro-hinges, hinge, bayonet, etc. , - at least two functional block modules, made with the ability to perform: - one unique function (homogeneous functional block modules) or - several related functions, such as a photo and video camera (heterogeneous functional block modules) or - a number of unrelated functions such as a source of autonomous power supply, a light sensor and the inclusion of automatic lighting), as well as - to combine the performance of the specified functions thanks to the combination of heterogeneous and homogeneous functional block modules in one device, and the specified functional block modules contain the basis - a sub-board (miniature printed circuit board), on in which microcircuits, microchips (including systems-on-a-crystal) and other electronic and a hardware components; functional block modules, made with the possibility of connecting with each other directly, when communication is carried out in the way of through-passing of information signals and power directly between functional block modules located close to each other, or through other functional block modules - for functional block modules that are not located close to each other; each functional block module has the shape of a parallelepiped, and at least one functional block module is made with the possibility of performing at least one of the functions of the device, according to the user's choice; at the same time, the functional block modules are made with the possibility of performing functions in the conditions of their arbitrary location, including the spatial arrangement of physically unconnected functional block modules, as well as information exchange with objects located outside the device. - magnetic means of fixing functional block modules, which are installed permanent and variable magnets (electromagnets, electropermanent magnets), which are used to fix functional block modules and ensure physical contact between them and for the transmission of power supply and information signals, as well as if necessary their separation and liberation. These magnets are located on the sides of the block module with a step that corresponds to the size of the side of the minimum block module. Four magnets (magnetic square) form the sides of a broken square, which can be connected to magnetic connectors located on the surface of the base substrate.

In yet another version of the invention, the case has auxiliary elements that represent image-forming devices (screens of various types), inserts made of various materials, including those with traces of mechanical processing (engraving, etc.), light-emitting elements, etc.

In yet another variant of the implementation of the invention, the functional block modules do not have a case as such, but are made by the compounding method of a specialized printed mini-board, on which components and elements determined by the given functionality are installed, as well as elements for physical fixation of the functional block modules and connectors for the transmission of power supply and information signals between functional block modules, which allows to minimize the dimensions and thickness of the functional block module, as well as to make it so that it corresponds to the largest thickness of hardware components; at the same time, the functional block modules are rectangular plates with an even, smooth surface without protruding parts, and the electronic elements of the functional block modules, thanks to the above-mentioned design, are protected from the ingress of liquids (moisture), small loose substances, as well as from other possible negative influences environment.

In yet another aspect of the implementation of the invention, a method of three-dimensional placement of functional block modules is disclosed, which includes connecting their sides to each other with the help of magnetic means of fixation, functional block modules containing permanent magnets, located in such a way that when connected sides of two opposite functional block modules, they are located exactly opposite each other. In addition, each functional block module has a system of variable magnets (electromagnets or electropermanent magnets), which are controlled by software and have a direction of action opposite to that of the installed permanent magnets, which allows for easy removal of the functional block module.

Another aspect of the invention discloses a method of connecting functional block modules to each other by their sides using magnetic means of fixing functional block modules, which consist of electromagnets and electropermanent magnets, which allows, if necessary, to connect functional block modules in assemblies and install or remove not each one separately, but a set number of functional block modules at once.

In yet another aspect of the implementation of the invention, a method of power transmission between functional block modules by direct contact during their physical connection, regardless of the location of the functional block modules relative to each other, through conductive contact surfaces located along the edges of the functional block modules, is disclosed.

At the same time, the power supply is transferred from the power source to the target functional block module through other functional block modules or directly, and the current-conducting contact surfaces do not have protruding parts, which allows the functional block module to have a smooth surface from the outside, and the current-conducting contact surfaces to prevent oxidation, optionally covered with a protective layer made of, including, but not limited to, gold, organic conductors, etc., which in turn will minimize the effect of moisture on conductive contacts.

In yet another version of the invention, power can be transmitted to other functional block modules (including specialized ones) capable of receiving and transmitting power wirelessly: acoustic, induction, optical, as well as in other ways. At the same time, functional block modules that carry out wireless reception/transmission of power supply can work separately (at a distance) from the main device.

In yet another aspect of the invention, a method of wireless transmission of information signals is disclosed, which includes the use of the specified functional block modules, and each of them contains elements for receiving and transmitting optical signals on its faces and sides; and each functional block module contains elements for converting optical information signals into electronic ones. The advantage of this method is the high speed of data transmission, as well as the possibility of the most efficient use in the future of functional block modules with optoelectronic systems (optical processors), while the elements of receiving and transmitting information are located in such a way that the process of receiving and transmitting optical information signals between two by the connected sides of different functional block modules is carried out even when the functional block modules are shifted relative to each other during operation.

In another aspect of the implementation of the invention, the transmission of information signals between functional block modules is carried out wirelessly using a high-speed standard for the transmission of information signals over radio channels (for example, M/i-

ER); despite the fact that each functional block module contains a transmitter/receiver of radio radiation. The advantage of this method is the ability to physically connect and remove block modules relative to each other at a certain distance, limited by the effective range of the radio radiation reception/transmission system, which allows information signals to be transmitted between completely different devices and their elements.

In another aspect of the implementation of the invention, the transmission of information signals is carried out in a way using contacts placed on the faces and sides of the functional block modules. Since the functional block modules are connected closely to each other with the help of magnetic means of fixation, their current-conducting elements (contacts) are connected at the same time.

Thus, when any number of different functional block modules are connected through external contacts, they are connected to a single network, the so-called "Temporal PCB", thanks to which they can freely exchange information signals.

Fig. 1 illustrates the general view of the device.

Fig. 2 is a diagram of the arrangement of block modules, as well as their comparative (relative) sizes.

Fig. C illustrates the substrate - the basis for placing block modules when there are free three minimum sections for installing block modules.

Fig. 4 illustrates the device from the front.

Fig. 5 illustrates the device from behind.

Fig. 6 illustrates the upper end of the device.

Fig. 7 illustrates a touch panel placed on the side (right) side of the device body.

Fig. va and 8b illustrates a sequential and gradual change in the transparency of the back cover of the device body (part of the back cover remains transparent to perform certain functions at the User's choice).

Fig. 9 illustrates an example of a single row connection of block modules with the same dimensions in the connection.

Fig. 10 illustrates an example of a single row connection of block modules with different sizes in the connection.

Fig. 11 illustrates an example of a multi-row/planar connection of block modules.

Fig. 12 illustrates an example of multi-row and multi-space connection of block modules.

Fig. 13 illustrates an example of multi-row and multi-space connection of block modules without one module.

Fig. 14 illustrates the general view of the block module with power supply channels and information channels.

Fig. 15 illustrates an example of the arrangement of magnets on block modules.

In fig. 1 illustrates a general view of the device, which includes a housing formed by the combination of the back cover 1, which optionally has a touch panel 2 on the side, and the top cover, which is the main screen C and, optionally, on the other side - a substrate-base 4 for placing functional block modules 5. At the same time, the back cover serves to fix the functional block modules 5 located on the substrate-base and give the device an appearance, shape and should determine the device model. The back cover 1, according to one of the variants of the implementation of the invention, can be made transparent or partially transparent and/or have transparent inserts in the upper part, at least inside have the shape of a rectangular parallelepiped, and the total thickness of the device can reach 15 mm. According to another version of the invention, the back cover 1 of the case can be opaque and can be made of metal, glass, wood, bone, plastic, rubber, etc. with applied patterns, paintings, engraving, etc., with variable transparency and color, with and without illumination. Also, the body of the device can be made and/or contain built-in decorative elements from metal, wood, plastic, including rubberized, rubber, glass (including its special versions, such as sapphire glass, vtayi diavv, dogePa diav5, etc. .), as well as other artificial or natural materials, while image-forming elements (screens of various types), inserts from various materials, including those with traces of mechanical processing (engraving, etc.) can be used as decorative elements, light-emitting elements, etc. The device can have any shape, arbitrary proportions, which are determined for each model individually. The device case may also contain a built-in battery 5.

In fig. 2 shows the base substrate 4, which is the reverse side of the main screen.

The substrate-base 4 serves for the placement of internal functional block modules 5 and their fixation. The base substrate has a coordinate grid 6 in the form of sections of the same size, which correspond to the size of the minimum square block module. Each section can be in a passive state, that is, without an installed functional block module, and in an active state, that is, with an installed block module.

On the surface of the base substrate are magnets and electromagnets (not shown). It is also possible to use permanent (impulse) magnets, the principles of which arrangement ensure maximum comfort and convenience when working with functional block modules, as well as with the device as a whole.

The specified magnets are located on the base substrate with a step that corresponds to the size of the section.

At least four magnets, the so-called "magnetic square", form the sides of the broken square, which can be combined with the magnetic connectors on the sides of the minimal functional block module.

In the middle of the "magnetic square" is an electromagnet with a power greater than the total power of the magnets of the magnetic square. The electromagnets are controlled by the software of the device and are selectively turned on (they are built into the sections of the substrate-base and are connected to the body of the device, to the power sources of the device and to the central processor of the device during its operation - through the interface of the main screen or through the side touch panel. After receiving instructions from the user to remove the functional block module(s), the electromagnets under the functional block module to be removed are activated. Due to the fact that the direction of the magnetic field is opposite to the direction of the magnetic square, such a functional block module is repelled from the base substrate and it can be removed without hindrance.

With the help of electromagnets, several block modules can be removed, for example, of the same type, which allows the creation of super-modules from several block modules that are easily transferred between different modular devices.

In addition, the "magnetic squares" on the substrate-base sections contain connectors for the transmission of information signals and power supply. This allows you to connect the internal functional block modules to each other through the base substrate, that is, through the back side of the main screen, and also allows you to connect the functional block modules to the body of the device, to the decorative screens on the body, the side panel, the built-in power supply , the main screen and

With block modules in a cassette. In this way, full interconnection of all parts of the device is ensured.

To install, remove and replace functional block modules 4, it is necessary to move the substrate-base with the main screen of the device (for example, up - as shown in Fig. 1).

After that, the user gets access to functional block modules.

In fig. The substrate-base 4 is illustrated with the functional block modules 5 installed on it. The location of the block modules relative to each other is completely arbitrary and is determined only by the presence of free space inside the device body. In this case, the figure shows as free three minimum sections 7 for installing functional block modules.

In fig. 4 shows the main screen 3. At the same time, the device can be equipped with auxiliary and additional screens, for which the outer sides of the device body can protrude. Additional screens can be virtual screens formed using projection technologies, which allows you to see three-dimensional images in the real world, as well as devices that create virtual, that is, images that do not exist in reality, in particular, with the help of augmented virtual reality glasses etc.

An alternative version of the invention provides for the location of the substrate-base on the back cover 1 of the case, separately from the main screen.

In fig. 5 shows the cassette 8, which, optionally, must be present in the device body and is used to install those functional block modules that are often replaced (inserted/removed), as well as for those block modules that need to perform their functions install at least one side outwards. In addition to the main screen, such "external" functional block modules include: photo and video camera block modules, sensors and sensors (optical) block modules, as well as connector block modules (outputs of various types for connecting external devices) .

At least part of the cassette, which is also part of the device body, is made transparent, which allows you to eliminate the problems of placing block modules of photo and video cameras, as well as optical sensors.

The body of the device can contain at least one cassette.

In fig. 6 illustrates an embodiment of the invention, in which one cassette 8 can contain outputs 9 for installing external information connectors and connectors for receiving and transmitting (516) power supply.

In fig. 7 illustrated touch panel 2, placed on the side (right) side of the back cover of the device housing. The device can provide many variants of the graphical interface, of which four main ones are given as one implementation option: - basic (main) 10 - call management 11 - music management 12 - photo/video camera management 13.

In fig. Figures 8 and 86 illustrate sequential and stepwise changes in the transparency of the back cover of the device housing from 0 to 100,905 transparency.

In fig. 9-15 illustrate functional block modules that are both the physical unit of the device and the functional basis for performing one or more related or related functions. The functional block module contains a complete set of hardware elements for this purpose, as well as means for fixing inside the device case, physical connection with other block modules and ensuring interaction with other block modules (transmission of power supply and information signals).

The main structural elements of block modules are: - the base of the block module - a subboard (miniature printed circuit board) on which microcircuits, microchips (including systems-on-a-crystal) and other electronic and hardware components are placed.

The use of one-sided or double-sided printed circuit boards, as well as multi-layer, flexible or multi-level boards (not shown in the figures) is assumed.

In fig. 14 illustrates one of the variants of the invention, in which each functional block module contains a device for receiving and transmitting information signals: a) by contact. In this case, inside the body of the block module there are channels made of material that conducts electric current, which go to the connectors 14 located on the faces of the block module in a special way, made on the basis of the calculation. b) by electromagnetic radiation (radio waves). In this case, each functional block module additionally contains two microchips that receive and transmit electromagnetic radiation (signals) over short distances (up to 0.5-1 m).

Such microchips can be located anywhere inside the body

From the functional block module. c) by optical (optoelectronic) transmission using laser radiation. In this case, each functional block module contains a center for receiving and transmitting information signals, as well as converters of light pulses into electronic ones and vice versa.

Optical signal reception-transmission channels are located on each of the free (functionally inactive) faces of the functional block module.

In the case of option "b", block modules can work and be controlled by a user who is physically separated from the device (provided it is connected to a power source).

In addition, each block module contains channels 15 and contact planes 16, which transmit power when touched.

These channels pass inside the functional block module and have exits in the center of each of its faces.

According to one of the variants of the implementation of the invention, functional block modules can contain a device for wireless reception of power from the power supply unit (which will ensure full encapsulation of the functional block module and its complete independence from the location of other block modules). At the same time, the main functional power supply module contains a device for wireless power transmission.

In fig. 14 illustrates how neodymium magnets 17 and electro-permanent magnets 18 are placed on the sides of the functional block modules. These magnets are arranged in a way that allows the functional block modules to be connected to each other, as well as to connect to the "magnetic squares" in the cassette and in the base substrate, namely, the magnets are located on the block modules with a step that corresponds to the size of the functional block module. Four "magnetic square" magnets form the sides of a broken square, which can be connected to the indicated magnets on the substrate-base. Two or more "magnetic squares" can connect block modules of large sizes. At the same time, the initial placement of magnetic connectors between each other is absolutely not important, because if you try to incorrectly connect functional block modules to each other, etc., on the sides on which there are magnets with the same poles, they will repel, and the opposite ones will attract, which automatically means, that the magnetic connectors will self-install into their normal position.

In addition, the block modules can have built-in micro-LEDs for illumination, which will allow to visually distinguish functional block modules of the same type, as well as be an indicator of the functionality of the functional block module. In addition, it will be natural to use backlighting to attract the user's attention.

Lighting can be provided either by using one or more LEDs in the partially transparent body of the block module, or by shining special decorative light guides that can be placed, for example, on the edges of the block module. The duration, intensity and frequency of the LEDs are determined by the software.

With one of the variants of the implementation of the invention, the block modules do not have a case and are made by filling the working volume (together with means of communication and connection) of the block modules with a transparent or translucent compound. Magnets and contacts for the transmission of power and information signals (optically or by other means) are pre-installed in the form for pouring.

As a result, each functional block module is sealed and has no protruding parts or details.

Information can be stored in separate functional memory block modules that use a) RAM b) PZP c) memristors that combine RAM and PZP.

In addition, it is possible to partially store information in any functional block module of your choice (for example, a central processor block module). Also, a solution is possible when the RAM of at least one block module can be used as RAM.

Information processing can be carried out according to two schemes: a) use of a central processor, which carries out general processing of information from the entire device. This option is acceptable for all devices, except for those that require the highest level of quality of work with the user's device, and therefore the highest speed of information processing; b) ensuring the possibility of integrating microprocessors and memory blocks into separate block modules.

This will reduce the load on the most resource-intensive block modules and reduce the load on the central processor.

It is also possible to operate several multi-core processors with parallel distribution of task threads.

Each of the above options can be built both on electronic and, in the future, on optical and optoelectronic processors, with an increase in the speed of information processing compared to electronic processors.

The driver of each functional block module is located in its memory chip, which allows storing not only the driver, but also a certain amount of other information.

Claims (7)

FORMULA OF THE INVENTION 1. Multi-purpose modular mobile electronic device with changeable configuration and functionality (BMMEP), containing functional block modules, made with the ability to transmit information and electrical signals for receiving, storing, processing, transmitting and displaying information, containing: a case that contains the back cover, which is made with the possibility of magnetic fixation of functional block modules and additional screens inside the case; and the top cover, one side of which is the main screen for entering and displaying information, and the other side is the substrate-base for placing functional block modules, using magnetic connectors; means for opening/closing the case, made in the form of guides for shifting the top cover relative to the back when opening and closing the case; at least two functional block modules that have the shape of a parallelepiped and are designed to perform: one unique function (homogeneous functional block modules), several related functions (heterogeneous functional block modules); unrelated functions, as well as combine the performance of the specified functions in one device by combining heterogeneous and homogeneous functional block modules; and the functional block modules contain a sub-board on which electronic and hardware components are placed, while the functional block modules are made with the possibility of direct connection with each other, when communication is carried out in the way of the through-passing of information signals and power directly between the functional block modules , located close to each other, or through other functional block modules that are not located close to each other; moreover, the specified functional block modules are made with the possibility of performing functions in the conditions of their arbitrary location, including the spatial location of physically not connected functional block modules, as well as the exchange of information with objects located outside of the device, and the magnetic means of fixing the functional block modules consist of installed permanent and variable magnets, magnets for fixing the functional block modules and ensuring physical contact between them, for transmitting power and information signals, including their disconnection and release, while the magnetic means of fixing the functional block modules are located on the sides sides of the functional block modules with a step corresponding to the size of the side of the minimum functional block module, and four magnets form the sides of the broken square, which are made with the possibility of connection with magnetic connectors that are located on the surface of the substrate-base. 2. BMMEP according to claim 1, which differs in that a touch screen, light-emitting elements, etc. are located on the side surface of the case. 3. BMMEP according to claim 1, which differs in that the means for opening/closing the case are selected from: microloops, hinges, bayonets, etc. 4. BMMEP according to claim 1, which is characterized by the fact that the functional block modules contain magnetic fixation means for connecting their sides, and the functional block modules that contain permanent magnets, which when connecting the sides of two oppositely located functional block modules are located opposite each other, while each functional block module contains on its sides a system of variable magnets, which are made with the possibility of being controlled by software and have the direction of action opposite to the action of the installed permanent magnets. 5. BMMELP according to claim 1, which is characterized by the fact that the functional block modules are connected to each other by their sides with the help of magnetic fixing means, which consist of electromagnets and electropermanent magnets, in an assembly, for installing or removing a given number of functional block modules. 6. BMMELP according to claim 1, in which each of the functional block modules on its faces and sides contains elements for receiving and transmitting optical signals, and each functional block module contains elements for converting optical information signals into electronic ones. 7. The method of receiving and transmitting electric power from/'to BMMEP, which includes the stage at which the reception and transmission of electric power to functional block modules is carried out using wireless communication: acoustic, induction, optical. her B. 3, Fig. 1 | . 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