SU517902A1 - Device for modeling scheduling tasks - Google Patents

Description

one

The invention relates to the field of analog computing and can be used to operatively solve problems of determining the optimal order of performing a complex of works while simultaneously distributing the resource between them taking into account the process conditions.

There are known devices for simulating scheduling tasks, containing a work model block, a communication simulation block, the first output of which and the output of the work model block are connected to the input logic, the graph topology modeling block, and the display unit.

To select the optimal topology of the network schedule due to the absence of criteria for changing it on such devices, complete non-choice of all variants is required, which makes it almost impossible to find the exact solution of problems of even a small dimension.

The purpose of the invention is to define the process of choosing the optimal network graphics topology. The ego is achieved by the fact that the proposed device comprises a communication state selection unit, the first input and output of which are connected respectively to the second output and input of the communication modeling unit, and the control unit. To the input of the control unit, connect the output of the modeling unit to the topology of the graph, and the output is connected to the second input of the communication state selection unit, the second output connected to the display unit. The communication modeling unit is made in the form of chains according to the number of simulated connections, connected in accordance with the topology of the graph, each of which contains nos.translatedly connected indies; the current factor, voltage source, switch, and diode.

FIG. 1 is given a block diagram of the device; in fig. 2 - schema tsenochki St. in fig. 3 - control unit.

The device is composed of block 1 of the modeling of the topology of the graph, the working cells of the block 2 of the work models and block 3 of the communication modeling are connected to the set of the sensor. The work model block consists of a set of known diode function converters, each of which is used to simulate the time-life characteristics of on-off work. A mode block; communication linkage consists of a set of chains of links connecting work models in accordance with the network topology.

Each communication chain of a communication modeling unit contains, in succession, a connected current indicator 4, a voltage source 5, a switch 6 (for which, for example, an electromagnetic relay is used) and a diode 7 defining the current difference. The voltage source 5 with the power disconnecting switch 6 can be switched on in the communication chain against the iravlepii in it, which provides two possible communication conditions: with or without a locking voltage source.

The current indicators 4 and the switches 6 of each communication chain are connected respectively to the first multi-channel (by the number of connections) input and output of the link state selection unit 8. To the second output and input of the block 8 are connected, respectively, the block At the display and the output of the block 10 of the control. The link state selection block is used to sequentially switch and memorize the state of the 1 and the links and can be made of any switching and storage elements (e.g., step finders and electromagnetic relays).

The input of the control unit 10 is connected to the terminals of the dial-up plateau of the graphic topology modeling unit corresponding to the initial and final vertices of the network model. The control unit contains a current limiter 11, in parallel with which two control chains can be connected using normally open relay contacts 12 and 13. The current limiter can be made according to any circuit having such a load characteristic that for a given current value the voltage value can vary within wide limits.

The first control circuit contains a series-connected current indicator 14, a capacitor 15 and a diode 16, and a voltage source 18 can be connected to the capacitor 15 of this control circuit using normally open relay G / contacts. The second control circuit, containing a current indicator 19, a capacitor 20, a diode 21, a relay 22 and a voltage source 23, is similar to the first one.

On the dial plate of block 1 of modeling the topology of the graph, the models of the work of block 2 and the links of block 3 collect the redundant model of the network graph under consideration, taking into account all possible work sequences and the interrelationships between them. The diode functional converters of the work model block 2 are tuned for time-life characteristics of the respective works. In all communications, the communication modeling unit 3 sets the voltage value of the locking sources 5. The magnitude of this voltage must be equal for all communications and large enough to ensure the locking of any network connection, while this value must be smaller the maximum voltage arising on any of the work models in the case of the minimum current specified for this work, in the case of a sutstzi in it, i.e.

conditions of existence of a minimum network flow. With the help of the current limiter 11, a current value is established corresponding to the total number of resources allocated for the execution of the whole complex of works. After such preparation, the device is turned on for operation, in the control unit 10, the contacts of the relay 17 of the first control circuit are closed for a short period of time.

The capacitor 15 is charged to a voltage higher than o6nj, its voltage of the network model is by a small amount of the voltage of the source 18.

The link state selection unit 8 carries out a test connection in the next chain of communication with the current by means of the switch 6 of the locking source 5, i.e. the link is locked. After that, in the control unit, the relay contacts 12 are closed, but if the total

the voltage of the network model is not raised, the discharge current of the capacitor 15 triggers the current indicator 14. The control pulse from the indicator 14 enters the communication state selection unit, with which

the checked communication is memorized, and the communication remains locked. In the absence of a control signal from the current indicator 14, the communication is not memorized and does not remain locked.

If during the next test locking of any connection, the voltage increases on the connections locked earlier and a current occurs in them, the current indicators 14 of these connections are triggered. In this case, in the block

10, the control contacts of the second control center relay 22 are closed for a short time, and a capacitor 20 is charged. The link state block bypasses the previously locked

Due to the presence of current, and from the control pulses of the current indicator 19, the connections that maximally reduce the network voltage of the network model when removing from them the locking voltage sources are sequentially selected. After the disappearance of the newly induced currents in all the previously locked connections, the contacts of the relay 12 of the first control circuit are closed, and in the case of the current indicator 14

The achieved congruence of the entire network model is remembered, the state of all links is maintained. In the absence of a control pulse from the current indicator 14 using memory elements, the state of the entire network model that was reached before this step is restored.

Thus, on each unit of operation of the device, a trial locking of the next connection with the current occurs while

eliminating the blocking voltage sources from those connections to the newly generated current that maximally reduce the overall voltage of the network model. If the total voltage of the network model does not increase as a result of the next step, it is remembered and

The new state of the entire network model is retained, otherwise, the previously stored state is restored. In this case, the first control chain controls the switching of the state of the entire network model, and the second one is used for the intermediate selection of links, the output of which blocking voltage sources maximally reduces the total voltage of the network model.

After a finite number of device operation steps, the total voltage of the network graphics model will only increase at each step. The achieved state of the model will correspond to the solution of the problem, since the resource at each step, due to the principle of minimum power, is distributed between works in an optimal way, and the resulting topology corresponds to the minimum execution time of the whole complex of works. The topologies of the desired network schedule will be determined by communications with the current, which are visually recorded on the display unit display panel, and the resource occupied in each of the works is measured by a milliammeter.

The use of new blocks in the device: a block for selecting the state of communications and a control block, as well as a constructive solution for the block of simulating communications and the interaction of all blocks of the device eliminates the need to thoroughly search all the options for changing the network topology when solving problems of synthesizing the optimal network schedule

and automates this process, and therefore the process of choosing the optimal network graphics topology is greatly simplified and accelerated.

Claims (2)

1. A device for simulating scheduling tasks containing a block work models, a communication modeling block, the first output of which and the output of a work model block are connected to the inputs of a graphics topology modeling block, and an indication block, characterized in that in order to simplify the process of choosing the optimal network graphics topology, it contains a link state selection block , the first input and output of which are connected respectively to the second output and input of the block simulation of communications, and the control unit, to the input of which the output of the modeling unit of the topology of the graph is connected, and the output is connected to the second input of the communication state selection unit, the second output of the connected to display unit. 2. A device according to claim 1, characterized in that the communication modeling unit is made in the form of chains according to the number of simulated connections, connected according to the topology of the graph, each of which contains series-connected current indicator, voltage source, switch and diode. neither ig.1 .6 g-g-