EP4162640A1

EP4162640A1 - Combinational distribution system for distribution of energy and matter

Info

Publication number: EP4162640A1
Application number: EP21748494.8A
Authority: EP
Inventors: Peter URANIC
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-06-05
Filing date: 2021-06-04
Publication date: 2023-04-12
Also published as: WO2021244692A1; DE102020003476A1

Abstract

The invention relates to a combinational distribution system for distribution of energy and matter, wherein the combinational distribution system is designed as a system of lines for distribution of energy or matter and has at least two sides, a side A (1) and a side B (2), which are reach connected by at least two lines (3), wherein the ends of the lines on side A (1) stand alone or are arranged in a plurality of predetermined groups in which they are connected to each other (4), whereas they are grouped and arranged (5) on side B (2) without being connected to each other, wherein two or more contact points (4) of the lines on side A (1) are combined such that only one of a plurality of combinations determines the address of one or more specific contact points (5) of the lines on side B (2) which are connected by means of the lines for distribution of energy or matter to combined contact points (4) of the lines on side A (1), and if energy or matter is sent via combined contact points (4) on side A (1), the lines deliver energy or matter only to specific contact points (5) on side B (2), or vice versa.

Description

Combinatorial distribution system for the distribution of energy and matter

description

The invention relates to a combinatorial distribution system for the distribution of energy and matter.

State of the art

Matter is a substance in a solid or liquid gas or plasma state that has mass and volume. Energy is the ability of a body or system to do work. Two systems are used to distribute and manage matter and energy: serially, whereby matter or energy is distributed in a line to specified destinations - addresses. parallel, whereby matter or energy is distributed in several lines to given targets - addresses.

With the serial system, all work components are controlled at once. The parallel system enables the separation and separate management of work components. While the serial system has only one address to which energy or matter is distributed, the parallel system has several addresses. Despite all of these and other features of both systems, none of them behave like a logical control component.

DE 699 06 299 T2 discloses a device for controlling several drawers. With this device, a large number of drawers can be moved in a furniture body by means of a power supply device.

DE 27 29401 C2 discloses a “specialized digital computer for statistical information processing”. A circuit-based solution is described which is based on the use of probability information processing methods. The productivity when investigating random processes, in particular when calculating their statistical characteristics, is significantly increased, the electronic circuit is simplified, the outlay on equipment is reduced and the dimensions are reduced.

DE 11 2016 003245.5 discloses a “resistive processing unit” with two connections, which has a first connection, a second connection and an active area. The active area brings about a non-linear change in a conduction state of the active area on the basis of at least one first coded signal applied to the first connection and at least one coded signal applied to the second connection. The active area is configured to locally execute a data storage operation of a training methodology based at least in part on the non-linear change in the line condition.

The disadvantage of the known systems and methods is that a large number of electronic components are required in order, for example, to control or the like. to enable.

The object of the invention is therefore to provide a system and a method which, by means of a few electronic components, enable reliable control for different possible uses. Disclosure of the invention

The invention is disclosed by the features of the main claim. Ausfüh approximately forms and further developments are the subject of the further claims following the main claim.

A combinatorial distribution system of energy and matter is disclosed, the distribution system acting as a logical control component.

The disclosed combinatorial distribution system is a system of power or matter conduits arranged by combinatorial logic. The combinatorial distribution system has two sides, one side A and one side B, which are connected to energy or matter lines. The ends of the lines are contact points of the system. Control or work components or an energy or matter system are connected to the contact points. On side A the contact points are grouped and connected, while on side B the contact points are grouped but not connected. Contact points on side A and side B can be used as system inputs or outputs. If the inputs are on the A side and the outputs are on the B side, then energy or matter is distributed by propagation, i.e. by dispersion. When the system inputs are on the B-side and the outputs are on the A-side, the energy or matter is distributed by accumulation, i.e. by accumulation. Lines are also transmission paths such as optical or magnetic transmissions, radio waves, lasers, light signals and the like.

For the combinatorial distribution system to function, two or more contact points on side A are combined in such a way that only one of several combinations is used to determine the address of certain contact points on side B. For this reason, the contact points on side A automatically have their specific address. When energy or matter is sent through combined contact points on side A, the lines deliver energy or matter only to certain contact points on side B. When energy or matter is sent through a contact point on side B, the lines deliver energy or matter to specific combined contact points on side A, which are connected to that contact point on side B.

In a first embodiment of the combinatorial distribution system, this has in particular 5 input contact points on side A, which are numbered from 1 to 5, and the letters alpha- "a". The first input is labeled "a1", the second input is labeled "a2", etc. The individual outputs and the contact points on side B are identified by a letter Omega "w" and a combination of numbers that represent the inputs to which this output is connected, e.g. B. "w1,2", "w1, 3", "etc. Using the application example and a formula, only two inputs - contact points are combined on side A. The auxiliary formula with which the maximum number of outputs can be calculated wB on page B, based on the number of contact points - inputs - aA on side A reads:

ÜB = CIA * (QA - 1) / 2

If the contact points on the B-side are used as inputs, there are more inputs than the outputs on the A-side. In this case the inputs on the B-side are identified by a letter alpha "a" and the combination of the output numbers on the A-side, e.g. B. "cd, 2", "cd, 3", etc. The outputs are marked with a letter omega "w" and a number, e.g. B. "w1", "w2" etc. The formula for calculating the maximum number of outputs - wA on side A versus the number of inputs - aB on side B is: The specific addresses to which contact points on side A and the contact points on side B are connected are obtained when the combinations of contact points on side A are named, whereby the combinations may not be repeated. In this example, with the maximum number of possible combinations without repetition, the 2 contact points on side A are as follows:

1 . 2 2, 3 3, 4 4, 5

1 . 3 2, 4 3, 5

1 . 4 2, 5 1, 5

It can be seen from this that in this example 10 combinations are possible without repetition. For example, if "1, 2" or "2, G is specified, it is the same combination of contact points on side A. For example, if there are 5 contact points on side A (A = 5) or 10 contact points on side B (B = 10), it is the same combinatorial distribution system. The difference is which side of the system is used as inputs and which is used as outputs. The lines of the combinatorial distribution system can be "polarized".

This means that each line can have several different physical states. In electrical engineering, for example, lines can be polarized positively (+) or negatively (-). In optics, when using glass fibers, they can be polarized, e.g. B. "red, green or blue", so "RGB". RGB is the color space that is formed by means of the colors red, green and blue. In hydraulics and pneumatics, pipes serve as lines for gases and liquids that have different pressures and Temperatures. By polarizing the lines, it is possible to "program" the system. This allows greater system possibilities. The formula for calculating the number of operational components - K, e.g. B. LETs (light emitting transistors), which can be controlled by the polarization of the lines, in terms of the number of how many different poles the line can have - p and the number of system outputs - w, is: K = p ^* w

The combinatorial distribution system can be produced as a modular or separate compact logic element with or without additional logic components or as part of a device, a machine or a system. The combinatorial distribution system can be used in all scientific areas, i.e. in electrical engineering, optics, pneumatics, hydraulics, mechanics, etc. Due to the design rules and functional principles of the combinatorial distribution system, which are always the same, this system is explained using a further exemplary embodiment in electrical engineering.

Alternatively explained, the combinatorial distribution system is processed with the combinatorics. The combinatorial distribution system has two sides, side A and side B. Side A and Side B can be either inputs or outputs of the system. If side A serves as system inputs, side B of the system is outputs and vice versa, if side B serves as system inputs, side A is the outputs of the system. In the case where the system inputs are on the A side and the outputs on the B side, matter or energy is dispersed by propagation. If the system inputs are on side B and the outputs are on side A, matter or energy is distributed by accumulation. There are lines on side A and on side B. If the lines have no shape, ie the space is used for the transfer of matter or energy, the term “contact points of the lines” is used on side A and on side B instead of the term “lines”. The point of contact is the beginning or the end of the line or the point at which matter or energy enters or leaves the system. The lines or contact points have the same purpose, they carry matter or energy from one to a specific address. The lines or the contact points of the lines on side A stand individually for them and each of them represents an address. The lines or the contact points of the lines on side B are grouped together in groups of 2 or more and each of these groups of lines or contact points represents an address on side B. Each line or contact point of the line in the group, where the address on side B is connected to only one line, is connected to the contact point on side A. Each line or the contact point of the line in the group, whereby the address on side B has the same name as the line for identification purposes, is directly associated with the contact point on side A that for example line 1 of address 12 on side B is connected to line 1 on side A. Line 2 of address 12 on side B is also connected to line 2 on side A. By connecting the lines on side B to the lines on side A, a combination of the lines on side A is created. This combination is also an address on side BDh that address 12 of side B is a combination of lines 1 and 2 of side A. To get a single unique address on side B, the combination of lines on side A should not be repeated. The combination of 1, 2 or 2.1 is the same combination. When designing a combinatorial distribution system, if the combinations of the lines on side A are repeated, a parallel combinatorial system is obtained, which means that at least 2 groups of lines on side B have the same address.

Another embodiment shows the application in the control of the LET: With a two-pole switch one of two poles (+ / -) is selected or left out in the middle position. By turning on two or more switches, electrical current is sent over the lines to the desired LET, which can then be turned on. Each has its own address and depends on how and which switches or inputs are combined. With this system several LETs can be switched on and controlled at the same time, since several switches can be operated at the same time. This example is used in different technologies, e.g .: large interactive touchscreens, computer architecture, switching on and off electrical machines and devices and operations, telecommunications - multiplexing and demultiplexing.

Further advantages and advantageous embodiments of the invention can be found in the following description of the figures, the drawings and the claims.

Further advantages and advantageous embodiments of the invention can be found in the following description of the figures, the drawings and the claims. An exemplary embodiment of the solution according to the invention is explained in more detail below with reference to the accompanying schematic drawings. They show schematically:

Fig. 1 shows an example of a design of a combinatorial distribution system,

Fig. 2 shows schematically an application in the control of a LET,

3a) to 3) c show an alternative explanation,

Fig. 4 shows a combination of the lines on side A for creating the addresses on side B,

Fig. 5 shows a Pascal triangle,

Fig. 6 shows the combinatorial distribution system with 6 lines on the A side, with 3 being combined as an example to obtain an address on the B side,

Fig. 7a) shows an example of the distribution of matter or energy according to Fig. 6, whereby on side B the fully active address 134 is given as an example, which is connected to the active addresses 1, 3 and 4 on side A,

Fig. 7b) shows an example of a fully active address 256 on side B, which is connected to other fully active addresses 2, 5 and 6 on side A and

Fig. 8 shows the application in the control of an LED.

The combinatorial distribution system shown in Figure 1 is a system of power or matter lines (3) arranged by combinatorial logic. The combinatorial distribution system has two sides, side A (1) and side B (2), on which the ends of the energy or matter lines or lines for the distribution of energy or matter, with which the two sides are connected, are arranged. The contact points (4, 5) are grouped and arranges. The control or work components or an energy or matter system are connected to the contact points. On side A (1) the contact points (39) are connected, on side B (2) the contact points are not connected. Contact points on side A (1) and side B (2) can be used as system inputs or outputs If the inputs are on the A-side (1) and the outputs are on the B-side (2), energy or matter is distributed by propagation, ie by dispersion, if the system inputs are on the B-side (2) and the outputs are on the A-side (1), the energy or matter is distributed by accumulation, ie by accumulation. In order for the combinatorial distribution system to work, two or more contact points on side A (1) are combined in this way that only one of several combinations is used to determine the address of certain contact points on side B (2). For this reason, the contact points on side A (1) automatically have their specific address. If energy or matter via combined contact points on side A. (1) is sent, the lines deliver energy or matter only at certain contact points on side B (2). When energy or matter is sent through a group of contact points on side B (2), the lines deliver energy or matter to specific combined contact points on side A (1) that are connected to these contact points on side B (B). The embodiment of the combinational distribution system shown in Fig. 1 has input contact points (4) on side A (1) numbered 1 to 5 and the letters alpha- "a". The first input is labeled "a 1", the second input is labeled "a 2", etc. Individual outputs such as the contact points (5) on side B (2) are identified by a letter omega "w" and a combination of Numbers marked that represent the inputs to which this output is connected, e.g. B. "w1,2 \" w1,3 "." Etc.

Fig. 2 shows the application in the control of a LET (light emitting transistor): With the two-pole switch (6) one of the two poles (+ / -) is selected or this is left out in the middle position. By switching on two or more switches, electrical current is sent via the lines (3) to the desired LET (8), which can then be switched on. Each LET (8) has its own address and it depends on how and which switches (6) or inputs (4) are combined. With this system several LETs (8) can be switched on and controlled at the same time several switches (6) can be operated at the same time. This example is used in different technologies, e.g. large interactive touchscreens, computer architecture, switching electrical machines and devices on and off, telecommunications - multiplexers and demultiplexers of signals, etc.

Figures 3a) and 3b) show that the combination of lines on side A are not repeated in order to obtain a single unique address on side B. A combination of 1, 2 or 2.1 is therefore the same combination. If, when designing a combinatorial distribution system, the combinations of the lines on side A are repeated, a parallel combinatorial distribution system is obtained, which means that at least 2 groups of lines on side B have the same address. The lines in the lines groups or the addresses on side B are not connected to the same lines on side A, as shown in Fig. 3c), since in this case a classic parallel system is shown.

In Fig. 4 is an example of how the number of addresses on side B changes when the number of combinations K is changed and there are 6 addresses on side A, is shown in the following table:

A = 6

Fig. 4 shows a combination of the lines on the A side to create the addresses on the B side which have 2 or more lines. By combining the lines on side A, the addresses on side B can be created that have two combinations of lines. A lot of combiners tion is marked with the letter K. The combination also shows how many lines an address on side B has. The formula by which a set of addresses on side B can be calculated compared to the number of addresses on side A is:

A = number of addresses on page A.

K = number of combined addresses on side A or number of lines of an address on side B.

B = number of addresses on page B

FIG. 5 shows how the relationship between some sets of the addresses on the A side, a number of combinations K and some sets of the addresses on the B side is represented in FIG. 5 in the form of a “Pascal's triangle”. In the table in FIG. 5, an example of a combinatorial distribution system, which is shown in FIG. 6, is marked in the “Pascal triangle”, marked with a black color.

Fig. 6 shows that the combinatorial distribution system on the A side has the 6 lines of which three are combined to achieve the B side address. This example shows that there are 20 possible combinations on page B - addresses without repetition. The specific names of the unique addresses on side B are obtained if all combinations K of the addresses on side A are written out.

7a) and 7b) show how matter or energy is distributed in the combinatorial distribution system shown in FIG. 6. If energy or matter is sent through a given combination of lines on side A, all lines are only active at a specific address on side B, ie matter or energy is distributed over all lines of this specific address. The other addresses on side B have wholly or partly inactive lines, as shown in Fig. 7a) and Fig. 7b). In Fig. 7a) on side B is the fully active address 134 and is connected to the active addresses 1, 3 and 4 on side A. In Fig. 7b) on side B is the fully active one Address 256 and is connected to active addresses 2, 5 and 6 on side A. When energy or matter is sent through a group of lines or an address on side B, the lines deliver energy or matter to several specific combined lines or addresses on side A that are connected to that address on side B.

The behavior and operation of the combinational distribution system can be used when:

• Control components are placed at the system inputs that determine which addresses will be active

• Working components are placed on the system outputs that only work if all lines of these outputs - addresses are active.

When the combinatorial distribution system is designed in this way, matter or energy is distributed to the target address and the desired work is performed.

The lines are polarized. The flow of matter and energy through cables is influenced by the physical properties of the cables such as dimensions, shape, composition of the material from which the cable is made, etc. By changing the physical properties of matter and energy such as quantity, potential, density, etc., the state of the line is influenced which distributes this matter or energy. These two phenomena are known as “polarization of the lines”, which describes the change from one physical line state to another physical state. On side B of the combinatorial distribution system, which is shown in the following table, groups of lines with 3 lines (K = 3) per group address are shown. Each of these 3 lines in a group address can be polarized by one or more poles P. Each “pole combination” - P can generate a “subaddress” - S. K = 3

It can be seen that the number of sub-addresses S increases with the number of poles P. This embodiment shows that sub-addresses created by the polarization of the lines, just like addresses, can be specific and unique, which means that matter or energy can be sent to a desired destination. By polarizing the lines, the total number of possible addresses of the combinatorial distribution system can be increased.

The combinatorial distribution system can be produced as a modular or separate compact logic element with or without additional logic components or as part of a device, a machine or a system. The combinatorial distribution system can be used in all scientific areas, ie in electrical rototechnology, optics, pneumatics, hydraulics, mechanics, etc.

Due to the design rules and functional principles of the combinatorial Ver distribution system, which are always the same, this system is explained using an example in electrical engineering. However, it can be transferable to other systems.

In pneumatics and hydraulics, a combinatorial distribution system can be designed as a system of rigid or flexible pipes or hoses made of rubber, plastic, metal, etc., or as a system of channels or holes through a material, etc. For electrical energy transmission, the combinatorial distribution system can have cables, look like a matrix in electronics, look like a printed copper plate or look like a microchip, etc. The combinatorial distribution system in optics can be formed from optical glass fibers or another material that guides light. In mechanics, a combinatorial distribution system can be manufactured as a system of levers, steel cables, gears, etc., with which mechanical energy can be transmitted to a specific address. For the purposes of biology and medicine, e.g. B. to treat some implants or to reconstruct the nervous system, the channels can be made of biological material. A combinatorial distribution system can be produced as a modular or separate compact logic element with or without additional logic components or as part of a device, a machine or a system. The rules of construction and the principle of operation of the combinatorial distribution system are always the same regardless of the branch of science in which the combinatorial distribution system is used.

Fig. 8 shows the application in the control of an LED (light emitting diode): With the two pole switch (6) one of the two poles (+ / -) is selected or this is left out in the middle position. By switching on two or more switches, electrical current is sent via the lines (3) to the desired LED (8), which can then be switched on. Each LED (8) has its own address and it depends on how and which switches (6) or inputs (4) are combined. With this system several LEDs (8) can be switched on and controlled at the same time, since several switches (6) can be operated at the same time. The application of this example takes place in different technologies, for example: large interactive Touchscreens, computer architecture, switching electrical machines and devices on and off, telecommunications - multiplexing and demultiplexing signals, etc. All of the features shown in the description, the following claims and the drawings can be essential to the invention both individually and in any combination.

List of reference symbols

1 - A side of the combinatorial distribution system 2 - B side of the combinatorial distribution system

3 - a conduction of energy or matter

4 - contact point - in one example input a1

5 - contact point - in one example output w1, 2

6 - two-pole switch 7 - electrical power supply

8 - LED / LET

A = number of addresses on side A K = number of combined addresses on side A or number of lines of an address on side B.

B = number of addresses on page B S = subaddress

Claims

Expectations

1. A combinatorial distribution system for the distribution of energy and matter, the combinatorial distribution system being designed as a system of lines for the distribution of energy or matter and having at least two sides, a side A and a side B, which are each connected by at least two lines , wherein the ends of the lines stand alone on the A side or are arranged in a plurality of predetermined groups at which they are connected to one another, while on the B side they are grouped and arranged at predetermined contact points without being connected to one another, characterized in that, that two or more contact points of the lines on side A are combined in such a way that only one of several combinations is used to determine the address of one or more specific contact points of the lines on side B, which are connected to the lines for the distribution of energy or matter with combined contact points of the lines on side A. n, and when energy or matter is sent through combined contact points on side A, the lines for energy or matter only deliver to certain contact points on side B, or vice versa.

2. A combinational distribution system according to claim 1, characterized in that each line forms an address on the A side and each group of lines on the B side is an address which contains at least two lines.

3. Combinatorial distribution system according to one of the preceding claims, characterized in that a contact point of a group of lines and thus addresses on side B is connected and combined therewith via a line with of the address on side A, whereby this connection as a combination forms, defines and names the address on side B.

4. Combinatorial distribution system according to one of the preceding claims, characterized in that combinations of line connections to addresses on sides A and B can only be used once in order to achieve a unique address on side B for each combination.

5. Combinatorial distribution system according to one of the preceding claims, characterized in that both side A and side B are either system inputs or outputs, or if the inputs are on side A, the outputs are on side B and vice versa.

6. Combinatorial distribution system according to one of the preceding claims, characterized in that in the case in which the system inputs are on the A side and the outputs are on the B side, matter or energy is distributed by propagation.

7. Combinatorial distribution system according to one of the preceding claims, characterized in that when the system inputs are on side B and the outputs are on side A, matter or energy is distributed by accumulation.

8. Combinatorial distribution system according to one of the preceding claims, characterized in that at least two addresses on side A simultaneously send matter or energy to a specific address on side B, which is assigned to these addresses.

9. Combinatorial distribution system according to one of the preceding claims, characterized in that matter or energy is sent from an address on side B to at least 2 addresses on side A which are assigned to this address.

10. Combinatorial distribution system according to one of the preceding claims, characterized in that by changing the physical properties of the lines, matter or energy, ie by polarizing the lines, several sub-addresses are generated at one address and thus the total number of possible system addresses is increased.

11. Combinatorial distribution system according to one of the preceding claims, characterized in that if the lines have no shape and thus space is used for transferring matter or energy, via contact points and / or on the sides A and B, which serve to convey matter or to send, conduct or receive energy, these having the function of lines.

12. Combinatorial distribution system according to one of the preceding claims, characterized in that the construction rules and the functional principle of the combinatorial distribution system are always the same, regardless of the scientific branch in which the combinatorial distribution system is used.