RU2069937C1 - Connector with spatial switching of channels for automatic telephone exchange - Google Patents

Abstract

FIELD: electric communication, automatic telephone communication systems. SUBSTANCE: for decrease of number of switching elements (electron or quasi-electron contacts or elements) input and output lines are divided into groups (planes), additional vertical lines integrated into vertical planes are inserted and connection lines integrating crossing points of output planes with verticals are added. Electron (quasi-electron) contacts are installed in all crossing points of lines. EFFECT: decreased number of switching elements. 1 dwg

Description

 The invention relates to telecommunication technology and can be used in automatic telephone systems to reduce the resources spent in the implementation of switching devices of automatic telephone exchanges while maintaining their ability to connect subscribers.

 It is known that in the general case, any automatic telephone exchange (PBX) includes switching devices (KP) [1] which are devices that, under the influence of control signals, can change the state of their conductivity by connecting the input to the output. In the general case, the KP is a multipole (1, p. 194, Fig. 14.1) having N inputs, M outputs and R control inputs, in which, when signals are received at one or more R inputs, one of the N inputs is connected to any of M exits. The most common gearboxes in the automatic switching technique are relays, non-contact finders and multiple connectors.

Known multiple coordinate connectors for ATS [1] which are made of multiple relays with group control, as well as multiple reed switches and ferride connectors, in which at each switching point of the input with the coordination output, the connector contains a number of vertical columns of contacts (verticals), each of which is attached holding electromagnetic Y _i (see [1] p. 203, Fig. 14.8a) and a series of selector magnets B _j attached to the horizontal, while N holding solenoids correspond to N inputs of the connector, and M selects to the magnets of the M outputs of the connector. The inputs and outputs are connected by closing the switching elements at the intersection of verticals and horizontals. Accordingly, the number of switching elements in such connectors is DM x N.

 The closest technical solution is electronic (quasi-electronic) connectors in a PBX with spatial switching (see [1] p. 237). In such a connector, at each switching point, there is an electronic element (contact) in the form, for example, of a transistor, an optocoupler, etc. having corresponding inputs for controlling their conductivity. Depending on the signal at the electronic contact (EC) control input, the conductivity between the horizontal and the vertical of the connector changes. The number of verticals corresponds to N inputs of the connector, the number of contours M outputs. The number of switching elements in such a connector is equal to D M x N.

The disadvantage of the connectors selected for the prototype of the inventive connector is a large number of electronic contact elements used for their manufacture, and when NM the number of switching elements increases according to the law N ² with increasing capacity of the connector (numbers N and M).

 The purpose of the invention is to reduce the number of switching elements of the connector by changing the spatial location of the switched lines while maintaining the total capacity and maintaining or expanding the switching capabilities of the connector.

The goal is achieved by the fact that in the connector with spatial switching of channels with N input and M output lines, they are combined into input A ₁ , A ₂ , A _n and output B ₁ , B ₂ , B _m planes, respectively, each of which contains K (K <N, K <M) input and output lines. The input and output planes A ₁ , A ₂ , A _n (n N / K) and B ₁ , B ₂ , B _m (m M / K) are parallel to each other. Additional lines (verticals) are introduced connecting the same input a _i and output b _i lines of all i-planes A and B and forming vertical planes C ₁ , C ₂ , C _h , and the number of vertical planes h determines the switching capabilities of the connector. The number of verticals in each plane C corresponds to the number K of input and output lines combined into input and output planes A _i and B _i . Also introduced connecting lines Z, combining the connection points of the verticals of the vertical planes C ₁ , C ₂ , C _h and the output lines b _i , b ₂ , b _{k of the} output planes B ₁ , B ₂ , B _m, respectively, and their number is mx h. At the intersection of the input lines with the verticals, the verticals with connecting lines, the connecting lines with the output lines and the output lines with the verticals, switching points are formed in the form of electronic (quasi-electronic) contacts with control inputs that electrically connect the input lines with the verticals, verticals with connecting lines, respectively connecting and output lines and output lines with verticals.

 New relative to the prototype is the partitioning of the total capacity of the connector N x M at the inputs and outputs into groups of K lines in each, the introduction of verticals and connecting lines, as well as switching points for the electrical connection of input lines with verticals, verticals with connecting lines, to the connector, connecting lines with output lines and output lines with verticals.

 The drawing shows a structural electrical diagram of a connector with spatial switching channels for the PBX.

 A connector with spatial switching of channels for a telephone exchange contains N input and M output lines located in the input A and output lines in parallel planes along K lines in each, h vertical planes C containing K lines (verticals), connecting lines Z between the output lines and verticals in the amount of hxm, switching elements x between the input lines and verticals and switching elements y between the output lines, verticals and connecting lines.

 The spatial connector is constructed as follows.

так, что все вместе они образуют так называемую входную плоскость A₁. Следующие К входных линий размещены аналогичным образом

, образуя входную плоскость A₂. Последняя n-я плоскость A_n размещена параллельно всем предыдущим

, причем в указанных плоскостях A₁ A_n входные линии

. Выходные линии расположены аналогичным образом. Каждые К выходных линий образует выходные плоскости B₁, B₂, B_m, причем все выходные плоскости параллельны между собой и параллельны входным плоскостям так, что

, а выходные линии в выходных плоскостях расположены так, что

. Количество входных линий во входной плоскости будет равно к, количество входных плоскостей будет равно n, общее количество входных линий будет равно N к • n. Количество выходных линий и выходной плоскости будет равно к, количество выходных плоскостей равно m, общее количество выходных линий равно M к • m. Через каждую входную и выходную линии а₁₁, a₂₁, a_n1, b₁₁, b₂₁, b_m1 перпендикулярно им приведена вертикальная линия (вертикаль) с₁₁.The number of input lines N and the number of output lines M is divided by an integer K each so that the resulting values of n and m are integer. This is achieved by selecting N, M, K so that when dividing N by K, an integer n is obtained, and when dividing M by K, an integer m is obtained. In the proposed connector K, the first input lines are parallel to each other

so that together they form the so-called input plane A ₁ . The following K input lines are placed in a similar fashion.

forming the input plane A ₂ . The last n-th plane A _{n is} placed parallel to all previous

, moreover, in the indicated planes A ₁ A _n input lines

. Output lines are located in a similar way. Each K of the output lines forms the output planes B ₁ , B ₂ , B _m , and all the output planes are parallel to each other and parallel to the input planes so that

and the output lines in the output planes are located so that

. The number of input lines in the input plane will be equal to k, the number of input planes will be equal to n, the total number of input lines will be N to • n. The number of output lines and the output plane will be equal to k, the number of output planes is equal to m, the total number of output lines is M to • m. Through each input and output lines a ₁₁ , a ₂₁ , a _n1 , b ₁₁ , b ₂₁ , b _m1 , a vertical line (vertical) with _{11 is} shown perpendicular to it.

A vertical line with _{12 is} drawn through each input and output lines a ₁₂ , a ₂₂ , a _n2 , b ₁₂ , b ₂₂ , b _m2 . Similarly, the verticals are drawn through all other input and output lines, including through the lines a _1k , a _2k , a _nk , b _1k , b _2k , b _mk a vertical line with _{1k is} drawn. The verticals with ₁₁ , with ₁₂ , with _1k form the so-called vertical plane with ₁ . Parallel to the vertical plane c ₁ there is a vertical plane c ₂ , which includes the verticals c ₂₁ , c ₂₂ , c _2к , and the vertical c ₂₁ passes through the lines a ₁₁ , a ₂₁ , a _n1 , b ₁₁ , b ₂₁ , b _m1 perpendicular to them . Vertical with ₂₂ passes through the lines a ₁₂ , a ₂₂ , a _n2 , b ₁₂ , b ₂₂ , b _m2 and perpendicular to them. Similarly, all other verticals are placed in the vertical plane with ₂ , including _2k, passes through the lines a _1k and _2k , and _nk , b _1k , b _2k , b _mk perpendicular to them. All other vertical planes are placed in the same way. The number of vertical planes is equal to h. At the intersection of the verticals with the corresponding input and output lines, there are switching points with switching elements. Moreover, through the switching points formed by the corresponding verticals and output lines, connecting lines z pass perpendicularly to them. In the drawing, the connecting lines are formed as z ₁₁ , z ₂₁ , z _m1 for the first vertical plane with ₁ , z ₁₂ , z ₂₂ , z _m2 for the plane with ₂ , etc. At the switching points formed by verticals with, output lines b and connecting lines z, there are three electronic contacts, one of which connects the output line to the vertical, the other vertical to the connecting line, and the third connecting line to the output line.

 Input, output lines, verticals and connecting lines are conductive busbars that are electrically isolated from each other.

 The connector operates as follows.

 If necessary, to connect one of the inputs to one of the outputs to the control inputs of the corresponding electronic (quasi-electronic) elements, a control voltage is supplied, the resistance of the electronic (quasi-electronic) elements changes, and therefore a connection is made between the selected input and output. The operation of the proposed device is conveniently considered in the following examples.

Example 1. Let it be necessary to make a connection between input 11 and output 21. At the switching point x ₁₁₁ , a control voltage is applied to the control input of the electronic (quasi-electronic) contact and the input line a ₁₁ is connected to the vertical with ₁₁ . At the switching point y ₁₂₁ , a control voltage is applied to the control input of the electronic (quasi-electronic) contact connecting the vertical with ₁₁ and the output line b ₂₁ and the vertical is connected with ₁₁ and the output line b ₂₁ . Thus, the input 11 is connected to the output 21 through the circuit: input 11, input line a ₁₁ , switching point x ₁₁₁ , vertical C ₁₁ , switching point y ₁₂₁ , output line b ₂₁ , output 21. If, for some reason, it is vertical since ₁₁ communication cannot be carried out (the vertical with ₁₁ will be occupied by another subscriber), then communication can be made through any other vertical that has a common switching point with the input line, and ₁₁ i.e. through the verticals with ₂₁ , with _h1 and the corresponding switching points .

Example 2. Let it be necessary to connect the input 11 and the output 22. The control input of the electronic (quasi-electronic) contact located at the switching point x ₁₁₁ is supplied with a control voltage and the input line a ₁₁ is connected with the vertical line with ₁₁ . Also, the control voltage is applied to the input of the electronic (quasi-electronic) contact located at the switching point y ₁₂₁ and connecting the vertical with ₁₁ and the connecting line z ₂₁ , thereby making the connection between them.

Such a control voltage is applied to the control input of the electronic (quasi-electronic) contact located at the switching point y ₁₂₂ and connecting the z ₂₁ line to the output line b ₂₂ , thereby communicating between them. The connection of input 11 with output 22 is carried out through the circuit: input 11, input line a ₁₁ , switching point x ₁₁₁ , vertical c ₁₁ , switching point y ₁₂₁ through an electronic contact (quasi-electronic) connecting the vertical to ₁₁ and connecting line z ₂₁ , connecting line z ₂₁ , the switching point y ₁₂₂ through an electronic contact connecting the connecting line z ₂₁ and the output line b ₂₂ , the output line b ₂₂ , output 22. All switching operations during communication between the input and output occur in one vertical plane. In this example, in a plane formed by verticals with ₁₁ , with ₁₂ , with _1k in a plane with ₁ . If the vertical or connecting line of this plane necessary for the communication between the input and output is occupied by another subscriber or it will be impossible to use it for other reasons, communication between the input and output can be carried out in any other free vertical plane. To communicate with input 11 and output 22, if it is impossible to use a vertical plane with ₁ , a plane with ₂ (. With _h ) will be used. In this case, communication will be carried out along the circuit: input 11, input line a ₁₁ , switching point x ₂₁₁ ( _{.x n11} ) through an electronic (quasi-electronic) contact connecting the input line a ₁₁ with the vertical with ₂₁ (. With _h1 ), the vertical with ₂₁ (.с _h1 ), the switching point y ₂₂₁ (. Y _h21 ) through an electronic contact connecting the vertical with ₂₁ (. С _h1 ) with the connecting line z ₂₂ (. Z _h2 ), the connecting line z ₂₂ (. Z _h2 ), switching point y ₂₂₂ (y _h22 ) through an electronic (quasi-electronic) contact connecting the connecting line z ₂₂ (.z _h2 ) with the output line b ₂₂ , the output line b ₂₂ , output 22.

 The technical and economic advantages of the claimed compounds in comparison with the prototype is as follows.

 The number of vertical planes in the proposed connector is selected depending on the number of inputs and outputs, the relationship between the numbers N, M, K, the destination of the device, etc. In each vertical plane, a connection can be made between K pairs of inputs and outputs, i.e., according to the number verticals in the plane.

 The number of electronic (quasi-electronic) contacts spent on the manufacture of the proposed device is much less than for the manufacture of existing connectors with spatial switching. This can be seen from the following example.

 Example 3. In a system of 100 inputs and 100 outputs for the manufacture of an electronic connector with spatial switching, selected for the prototype, the number of electronic (quasi-electronic) elements D N • M 10000 is required. In this case, the condition for the possibility of communication of 100 pairs of inputs and outputs at the same time is fulfilled.

In the manufacture of the inventive connector with spatial switching of the same speed, the number of electronic elements D ¹ N • h + M • h • 3 will be required. At NM 100, K 10, nm 10, h 10; D '4000. The number of vertical planes h 10 selected from the condition of the possibility of communication of 100 pairs of subscribers at the same time. With an increase in the number of inputs and outputs, the value of the fraction D / D ¹ increases sharply, which makes it promising to use the invention in systems with a large number of inputs and outputs.

Claims (1)

Spatial switched channel connector for an automatic telephone exchange, containing N input and M output lines forming a switching matrix with a capacity of MxN, characterized in that the N input and M output lines are divided into groups of K lines in each (K <M; K <N ), each of which forms the input planes A ₁ , A ₂ , A _n (n N / K) and the output planes B ₁ , B ₂ , B _m (m M / K), placed parallel to each other, with the same input a ₁ , a _2, a _k and the output b _1, b _2, b _k lines of planes a and B are parallel to each other and vertical lines are laid same name via input and output a _i b _i i-line ies planes A and B and forming the vertical planes C _1, C ₂ .C _h, where h identifies the number of switching possibilities of the connector, wherein the number of vertical lines in each C plane is equal to K, and connecting lines Z laid through the intersection points of the verticals of the vertical planes C ₁ , C ₂ , C _h and the output lines b ₁ , b ₂ , b _k in the output planes B ₁ , B ₂ , B _m, respectively, and their total number is m • h, while at the intersections of the input lines with verticals, verticals with connecting lines and, connecting lines with output lines and output lines with verticals, switching points are formed at which installed switches that connect respectively input lines with verticals, or verticals with connecting lines, or connecting lines with output lines, or output lines with verticals.