SU598094A1 - Resistive lattice model unit - Google Patents

Description

one

The invention relates to analogue computational techniques and can be applied for solving boundary value problems of field theory.

Known resistive mesh models, consisting of e. , from identical 2D nodal points l. However, the known devices can be used only in the simulation of two-dimensional problems. The closest to the invention by technical

"The device is a resistive mesh node that contains the first code control its resistor connected to the first coordinate point on the axis of the node and with the grid point of the grid model, the second and third code-controlled resistors, power pin 21.1 This knot cannot be used also when modeling three-dimensional tasks.

The aim of the invention is to expand the field of application of the node of the resistive grid model by providing the possibility of restructuring during modeling. three-dimensional tasks. In the described node, this is achieved by the fact that it contains two-position switches, and the opening contacts of the first, second and third keys are connected to the node point of the segmental model connected to the first coordinate output along the axis and the first coordinate output along the axis of the node, moving to (I} the tact of the first two-key switch is connected via the second code-controlled resistor to the movable contact of the fourth positioning key, the opening contact of which is connected to the second coordinate output along the X axis of the node, the closing contacts n the fourth and fourth position keys, respectively, are connected to the second and third coordinate pins on the node axis t, the closing and movable contacts of the second two-pip key are connected to the first and second y axis pins, the third contact pin of the third double-sided key is connected to the fourth coordinate pin on the axis 2 nodes, the movable contact of the third two-position switch through the third code-controlled resistor is connected to the push-pull contact of the fifth two-position key, disconnecting to ntakt soeajroeH which, with the power bus, make contact dvupozitsnonnogo fifth switch is connected to n-tm coordinates gaym output axis

node.

The drawing shows the described unstep grid model nse grid model.

It contains two-position switches 1-5, code-controlled resistors. 6-8, nodes (y point 9, coordinate pins 10 and 11 on the axis, coordinate pins 12 and 13 on the y axis, coordinate pins 14-18 on the 2 axis, power supply 19 and adjacent connection points (nodal points)

grid model.

A control signal is supplied to all two-position keys of each node, which translates the moving contacts of the keys from one position to another. The section of the grid model, containing the key node and three node points 2Q-22 adjacent to the key node, can be in one of two states: two-dimensional or three-dimensional. In the two-dimensional state of the grid section of the model, the movable contacts of the keys 1,2,3,4, and 5 are in a normally closed position. In the three-dimensional state of the grid model, the movable contacts of the keys 1,2,3,4 and 5 are in the normal position. The properties of the key node are provided by the following connections. The node point 9 of the key node is connected to the first coordinate of the X axis of the node, which in the mesh model or connected to the second coordinated terminal 11 along the t axis of the adjacent key node is the outer & n terminal point of the node Node 9 also connected The coordinate viewpoint 14 is on the IL axis of the node, which, in the 5th and 1st states of the grid model, is the output of the NODE point 22 along the 3 axis. With the node point 9, the key node is connected to the cycles of the two-position keys 1,2 and 3. The movable contact of the two-positive key 1 is connected to one output of the 7 g code resistor, the other output of which is connected to the movable contact of the two-position key 4. Closing contact i of the first two-position key 1 is connected to the coordinate terminal 15 along the axis of the 2 nodes, which in the grid model is connected to the “nodal point 20 ... The movable contact dvupozinionnogo key 3 is connected to the coordinate output 13 on the Y axis of the node. The closing contact of the two-position key 3 is connected to the coordinates

with a pin 12 along the axis of the node, which is §; The mesh model is attached to a nodal point 22.

Open Contact Duplex

key 4 is connected to the second coordinate output 11 along the X axis of the node, which in the grid model is either connected to the first coordinate output 10 along the X axis of the adjacent key node, or is the outermost output of the extreme nodal point along the X axis. Closing contact of the two-position key 4 connected to the coordinate output 16 along the axis 2 of the node, which in the three-dimensional state of the grid model is

the house of the nodal point 20 along the axis b,

The movable contact of the two-position key 2 is connected to one pin of the code input {equivalent resistor 8, the other pin of which is connected to the movable contact of the two-position key 5. The closing contact of the two-position key 2 is connected to the coordinate pin 17 on the axis 2 of the node, which in the grid model is connected to a nodal point 21. The opening contact of the two-position key 5 is connected to the sutured power 19. The closing contact of the two-position key 5 is connected to the coordinate output 18 along the axis I. of the node, which is in the three-dimensional state of the grid model are vtodom nodal point 21 on the spar. In the two-dimensional state of the grid model section, the code-controlled resistors 7 and 6 of the key node are used as resistors along the coordinate axes X and for the node 9, and the code-controlled resistor 8 of the key node is used as an additional resistor for connecting the power supply 19 with the node 9. In the three-state state of the grid model 1, the one-directional resistors 6, 7 and the key node are used as the resistors along the coordinate axis iS, for the nodal points 2О-22: the node point 9 is not the nodal point of the model net; nodes of the grid model can be given a common control signal. In this case, the All Grid Model assumes one of two states: two-dimensional or three-dimensional. However, there is a wide class of three-dimensional problems, for example, modeling of geological formations, oil fields and groundwater, which are characterized by multi-layered areas with partial overlap of layers. When modeling these areas, one part of the grid modeti can be used in a two-dimensional state, and the other part can be used in the trickle state, for this purpose, for key nodes located in different parts