RU95416U1 - DEVICE FOR MODELING ROUTES - Google Patents

Abstract

 1. A device for modeling routes, including link models equipped with communication channels in opposite directions, the first and / or second ends of communication channels of link models are connected according to the topology of the graph and / or routes, respectively, with the second and / or first ends of communication channels of models of adjacent links, at least the communication channel of one link model is equipped with a counter-signaling recorder, the output of which is connected to the output of the link model, characterized in that the device is additionally equipped with determinant but matching simulated routes modeling requirements, whose input is connected to the output of at least one model unit. ! 2. The device according to claim 1, characterized in that at least one link model is additionally equipped with the device according to claim 1, the determinant of which is connected to the control input of the link channel key of the link model.

Description

The inventive utility model relates to the field of computer technology, namely, devices for modeling graph routes, used, for example, in solving problems whose conditions can be expressed in the form of graphs and their matrices, in particular, problems of finding Hamiltonian routes.

A device for route modeling is described in the Vperyod newspaper No. 9 (7489), January 20, 1990, Leningrad-Pushkin, p. 4. The prototype device contains link models equipped with communication channels in opposite directions. The first and / or second ends of the communication channels of these link models are connected in accordance with the topology of the graph and / or routes, respectively, with the second and / or first ends of the communication channels of the models of adjacent links. At least in one link model, the communication channel is equipped with a counter-signaling recorder, the output of which is connected to the output of this model. That is, the output of the model, in this case, is the output of its registrar.

The disadvantage of the prototype device for modeling routes is the exponential increase in the cost of modeling routes with an increase in the number of vertices in the graph.

The task underlying the utility model is to reduce the cost of route modeling, by simulating a single set of the entire set of routes.

The problem is solved in that the device for modeling routes contains link models equipped with communication channels in opposite directions. Moreover, the first and / or second ends of the communication channels of link models are connected, according to the topology of the graph and / or routes, respectively, with the second and / or first ends of communication channels of the models of adjacent links. In at least one link model, the communication channel is equipped with a counter-signaling recorder, the output of which is connected to the output of the link model.

New is that the inventive device is additionally equipped with a determinant of compliance of the simulated routes with the modeling requirements, the input of which is connected to the output of at least one link model.

The specified set of features of the first independent claim is a device that is a model of routes of the R-th order, for example, the first. With minimal modeling requirements, it allows you to solve the problem with costs equal to the cube of the number of vertices in the graph.

In addition, in accordance with the second paragraph of the formula in the inventive device, at least one link model is additionally equipped with a device for modeling routes according to claim 1. / route model of (P + 1) -th order, for example, second /, the determinant of which is connected to the control input of the key, which is equipped with the communication channel of the specified link model. This allows us to solve the problem with the maximum modeling requirements with costs of the seventh degree.

Using the claimed device (first order) allows you to use it in relation to the individual links of the routes, which, in turn, allows for this additional use (second order) to be additionally used in the device (third order), etc.

The principle of "nesting dolls" when the whole contains a part similar to the whole, and this part contains a subpart similar to the whole, etc., illustrates the technical solutions.

The utility model is illustrated by the following drawings.

Figures 1 and 2 are examples of graphs. Figure 3 - device for modeling routes of the R-th order. Figure 4 is a model of the P-th order top link in the P-order route model, equipped with the (P + 1) th-order model. 5 is a model of a P-order branch-link in a P-order route model equipped with a (P + 1) -th order model of routes. Fig.6 is a route model of the graph depicted in Fig.2. 7 is a graph illustrating the reduction in cost of route modeling.

In the figures and in the text of the description, the following notation is used for link models. Models of vertex links are indicated by three-digit indices, the first position of which is the number 2 - the designation common to all models of vertex links, the second position is the number of the vertex that is modeled by this model, and the third position is the number of the point that is modeled by this link model vertices. Models of branch-chain links are indicated by four-digit indices, at the first position of which is the number 3 - the designation common to all models of branch-chain links, at the second position - the number of the vertex from which the branch modeled by this model of branch-chain branches originates, in the third position - the number the point from which the branch modeled by this model originates, in the fourth position is the number of the vertex at which the branch modeled by this branch-link model enters. The numbers of the vertices and points are indicated by numbers and letters.

An example of modeling routes of a graph with an arbitrary number of vertices and branches (Fig. 1). The device 1 / P / (Fig. 3) contains models of link tops 2 and model of link branches 3 provided with communication channels 4, the first 5 and / or second 6 ends of communication channels 4 of these models of links 2, 3 connected in accordance with the topology of the graph and / or routes, respectively, with the second 6 and / or first 5 ends of the communication channels 4 of the models of adjacent links 2, 3. At least in one model of the link 2, 3 the communication channel 4 is equipped with a recorder 7, the output of 8 of which is connected to the output 9 of this model of link 2, 3. In addition, the device 1 / P / is equipped with a determinant 10, made for example, in the form of an AND element, the input 11 of which is connected to the output 9 of at least one link model 2, 3.

Flows of any type of energy, for example, alternating electric current, are sent to the entry of communication channels 4 into the device 1 / P /. If energy flows in opposite directions through the communication channel 4 of the link model, for example, 2.A.1., Then the recorder 7 located on this communication channel 4 is brought into operation and from its output 8 they send a signal to the output 9 of the link model 2 .A.1. To the input 11 of the determinant 10, all necessary pulses are sent from the outputs of 9 models of links 2, 3, and if the determinant 10 is brought into operation, then the set of all pulses is stored at the outputs of 9 models of links 2, 3, which are one formed signal from the pulses, each of which indicates the presence of certain links in at least one of the simulated routes, which can be fixed in any form.

Another example is represented by a device where at least one model of link 2, 3 is equipped with the inventive device 1 / P + 1 / (Figs. 4, 5), the output 12 (Fig. 3) of which determinant 10 is connected to the control input 13 ( figure 4) key 14 (figure 4), which is equipped with a communication channel 4 of the specified model link 2, 3, as follows.

On the occurrence of communication channels 4 in the device 1 / P + 1 /, for example, in links 2.E.K. (figure 4) and 3.K-1.E. (Fig. 5), energy flows are sent, from the triggered registrars 7, pulses are sent to the inputs 11 of the determiner 10 through the outputs 9 of the corresponding models 2, 3. If the determiner has received all the necessary pulses (for example, as an “I” element), then it is brought to operating condition and from its output 12 send a signal to the control input 13 of the key 14 of the corresponding link 2, 3 (2.E.K. or 3.C.-1.E.) of the device 1 / P /, the key 14 is brought into working a state that allows the communication channel 4 of this link 2, 3 to transmit energy in opposite directions and the recorder 7 is brought into working th state, whereby the output from the recorder 7, 8 through the outlet 9 of the link 2, 3 sends a pulse to the input 10 of the device 11, the determinant 1 / R /. This allows you to simulate routes with different requirements, for example, excluding routes that do not pass these links.

If it is necessary to transmit the signal generated in the device 1 / P / further (beyond its limits, for example, on the display), the output 12 of the determinant 10 can be connected to the control input 15 (Fig. 3) of the trigger 16, the signal input 17 of which is connected to the output 9 corresponding model of the link 2, 3, for example, 2.Е.n + 1. In this case, as a result of bringing into operation the recorder 7 of the communication channel 4, link models 2. 3 and determinant 10, the corresponding trigger 16 is also brought into operation, which will provide the possibility of outputting the generated signal outside the device 1 / P / in the form of a set of pulses the outputs of 18 triggers 16. In addition, the described device and its elements, if necessary, for example, when solving the traveling salesman problem, can be equipped with known devices for input-output and processing information about route parameters and their sound nyah, allowing further perform input and output operations and processing of relevant information. Due to the triviality described in this paragraph, its content is not included in the claims.

To solve the problem of the Hamiltonian graph, the following example of a device for modeling routes is given and its operation when modeling routes in column G at four vertices (Fig. 2). It should be determined whether there exists at least one closed route in the graph G that includes all the vertices exactly once.

This device 1/1 / (Fig.6) contains models of links 2.A.1, 3.A.1.C., 3.E.2.C., 3.B.3.C. and 3.B.4.A., connected by communication channels 4 in accordance with the topology of column G. In each model of link 2, 3 its communication channel 4 is equipped with a recorder 7, output 8 of which is connected to output 9 of this model 2, 3, which connected to the input 11 of the determinant 10. In addition, the links 3 are equipped with devices 1/2 /, the outputs 12 of the determinants 10 of which are connected to the control inputs 13 of the keys 14, which are equipped with communication channels 4 of these models of links 3.

In turn, the route model 1/2 / link 3.A.1.S. device 1/1 / contains model links 3.A.1.C. and 3.B.2.A., connected by communication channels 4 in accordance with the topology of column G. Communication channels 4 of these models of links 3 are equipped with registrars 7, the outputs of which 8, through the outputs 9 of these models of links 3 are connected to the corresponding inputs 11 of determinant 10 .

Devices 1/2 / of other models of links 3 of device 1/1 / are constructed in the same way, with the only difference being that they contain other models of links 2, 3. So the second-order route model 1/2 / link models 3.E.2.C. 1/1 / device contains models of 2.AL, 3.E.2.C., 2.C.3 links. and 3.B.4.A., device 1/2 / link models 3.B.3.C. device 1/1 / contains models of links 3.C.2.V. and 3.В.3. С., and the device 1/2 / link models 3.В.4.A. device 1/1 / contains models of links 2.A.L, 3.E.2.C., 2.C.3., 3.B.3.C., 3.B.4.A. and 3.A.1.C .. Moreover, the last link model is equipped with a device 1/3 /, the output of the determinant 10 of which is connected to the control input 13 of the key 14, which is equipped with the communication channel 4 of this link model 3.A.1.C. Route model 1/3 / link models 3.A.1.C. devices 1/2 / link models 3.В.4.A. device 1/1 / contains models of links 3.A.1.C. and 3.B.2.A., connected by communication channels 4 in accordance with the topology of column G. Communication channels 4 of these models of links 3 are equipped with recorders 7, outputs 8 which, through the outputs 9 of these models of links 3 are connected to the corresponding inputs 11 of the determinant 10.

To ensure the operation of the entire device 1/1 / from a single power source, in the models of links 3, which are equipped with devices 1/2 / and 1/3 /, additional paths 19 (6) of communication channels 4 are introduced, bypassing the registrars 7 and keys fourteen.

Since there are four vertices in column G, all determinants 10 of device 1/1 / are made in the form of “I” elements with four inputs 11, each of which corresponds to the occurrence of a certain vertex in at least one simulated route. If determinant 10 is triggered, then each link from model 3 of which a signal was input to input 11 of determinant 10 is included in many routes visiting all the vertices of column G. The operation of the described device 1/1 / is as follows. For example, an alternating current is sent to the entry of communication channels 4 into the route model 1/1 /, which passes through all models of links 2, 3. Registrars 7 of those models of links 2, 3, in which there are no keys 14 of communication channels 4, are triggered immediately from the outputs of 8 registrars 7, through the outputs 9 of these models of links 3, pulses are sent to the corresponding inputs of 11 determinants 10. The work of the remaining registrars 7 occurs only if the corresponding determinant 10 has worked, from the output of 12 of which they send a pulse to the input 13 of the control key 14, to A communication channel 4 of the corresponding link model 3 is provided with (with the recorder 7).

Thus, in the device 1/1 / only from the output 8 of the recorder 7 of the link model 2.A.1. through its output 9, an impulse is immediately sent to the input 11 of the determinant 10 corresponding to the vertex A, and in the other models of links 3, route models 1/2 / and 1/3 / work in the same way. As a result, in link models 3.A.1.C. and 3.B.3.C. devices 1/1 / and 3.A.1.C. devices 1/2 / did not work registrars 7, because the keys 14 did not come into operation, due to the fact that the identifiers 10 of devices 1/2 / and 1/3 / did not work, because not all of their inputs 11 received pulses from the registrars 7 link models 3.

In the link model 3.E.2.C. devices 1/1 / all components bring into operation, in particular, determinant 10 of device 1/2 /, and from output 8 of recorder 7 through output 9 of this model of link 3.E.2.C. send pulses to the corresponding vertices E and C inputs 11 of the determinant 10 of the device 1/1 /.

In the link model 3.B.4.A. in his device 1/2 / the registrars of 7 link models 3.B.3.C. and 3.A.1.C did not work, and in the latter, due to the fact that his key 14 could not be brought into working condition due to the lack of operation of the determinant 10 of its device 1/3 /, since only three of the four necessary pulses were received at its inputs 11. In other models of links 2.A.1., 3.E.2.C., 2.C.3. and 3.B.4.A. the registrars 7 are brought into working condition and from their outputs 8, through the outputs 9 of these models of links 2, 3, they send pulses to the corresponding inputs 11 of the determinant 10, which bring it into working condition and from its output 12 send a signal to the control input 13 of the key 14 link models 3.B.4.A. devices 1/1 /, which bring the key 14 to working condition and as a result of the operation of the recorder 7 from its output 8, through the output 9 of this model of the link 3.B.4.A., they send a signal to the inputs of the determinant 11 corresponding to the vertices A and B 10 device 1/1 /, which bring it into working condition.

The resulting pulse at the output 12 of the determinant 10 of the device 1/1 / indicates that the graph G of the Hamiltonians and its only Hamiltonian route: A-E-C-B-A, since the recorders 7 were brought into operation only in link models of this route - 2.A.1., 3.E.2.C. and 3.B.4.A. devices 1/1 /. The set of pulses at the outputs 9 of these link models is a signal generated and stored (in the form of a record).

The graph (Fig.7) shows the costs of implementing the known technical solutions / 2 to the degree n / and the costs of implementing the claimed technical solutions / n to the seventh degree /. This is due to the technical and economic effect achieved by the claimed device, which is expressed in reducing the number of structural elements in specialized devices, the number of operations in universal computing devices and the like.

The possibility of reusing the utility model in any sorting problems, for example, in solving traveling salesman problems, on the sum of subsets, on Hamiltonianity and others, ensures the industrial applicability of the utility model. It can be implemented in a variety of ways using any form of execution of link models and the entire device, any form of communication channels - electrical, optical, sound, etc. For example, transceiving and processing radio signals of the device, various topologies of integrated circuits of both individual link models and the entire device can be used as link models.

Claims (2)

1. A device for modeling routes, including link models equipped with communication channels in opposite directions, the first and / or second ends of communication channels of link models are connected according to the topology of the graph and / or routes, respectively, with the second and / or first ends of communication channels of models of adjacent links, at least the communication channel of one link model is equipped with a counter-signaling recorder, the output of which is connected to the output of the link model, characterized in that the device is additionally equipped with determinant but matching simulated routes modeling requirements, whose input is connected to the output of at least one model unit. 2. The device according to claim 1, characterized in that at least one link model is additionally equipped with the device according to claim 1, the determinant of which is connected to the control input of the link channel key of the link model.