NO133488B - - Google Patents

Description

Automatic telephone station.

The invention relates to an automatic telephone station for telephone systems comprising several arbitrarily numbered stations in an arbitrarily designed network, intended to directly establish a call connection through the above minimum number of stations continuously available for the occasion connecting path between a calling and a called station, taking into account part of all alternative connection routes through the network, part of any changes and blockages of traffic routes in the network, as the body in a calling station sends out a call signal that indicates at least the number of the desired called station, and where each station contains devices V that determine whether an incoming call is directed to this station, and when that is the case sends a response signal backwards through the call channel (e.g. TA) through which the call comes.

According to the invention, this is achieved by means of a common control body for the entire telephone station (Pl—P5,MR,Q1—Qp) which registers and compares the call signals for all outgoing calls present in the station at the same time and stops a call as long as a previous call with the same call signal exists in the station, and a group selector device (GA—GE) through which a calling incoming call channel (e.g. TA) in a traffic path at a call directed to another station spreads the call signal to a free outgoing call channel (TB, TC, TD ) in each of all other, non-blocked traffic channels outgoing from the station, as well as by the signaling body, (RA) which receives the said response signal, and partly forwards this backwards through the incoming call channel, partly causing the disconnection of all outgoing selected by the group selector device for the propagation of the call signal call channels other than the one through which the response signal is received.

The call signal in the above-described switching device can be designed in different ways. If the call signal indicates only the called station's number, only one connection can be made to each station at a time. This entails requirements for fast switching processes. By letting the call signal indicate both the caller and the called station's numbers, it is achieved that the restriction is limited to only one connection at a time being connected between two given stations in the network. More unlimited connection possibilities can be achieved by letting the call signal indicate both the calling and the called station's number and also the number of a switching device in the calling telephone station. This switching device can be a link in a closed, relatively short relay chain, which is moved forward one step with each call originating from the station. The number of the most recently connected extension is assigned to the last outgoing call. The switching device can also be the register in the calling station, which controls the connection, as the register's number is included in the call signal.

The invention will be described in more detail below with reference to the attached drawings, fig. 1 — fig. 3.

In fig. 1 shows a number of telephone stations A—K connected by means of groups of wires or conversation channels ti—tl6, which form a routed, arbitrarily designed network with a plurality of alternative connection paths between the stations. Each station A — K can be surrounded by substations connected by means of connection lines, which form a star-shaped local area network as shown for stations F and H. The substations are considered here as parts of the respective main station so that calls to and from these are equated with calls to and from the main station. The internal traffic within a main station and associated substations is outside the scope of this description.

A call from e.g. station A to station C can be connected via a plurality of different connection paths, e.g. tl+t4, t2 + tl4, tl + t3 + tl4, t2 + t3 + t4, tl + t5+t6, t2+tl3 + tl5, etc. According to the invention, the connection sequence is as follows: A wire in each of the wire bundle ti and t2 is selected , and a call signal indicating station C is broadcast on both lines. The call signals are received in stations B and D and a line in each of the line groups t5, t4, t3, resp. t3, tl4, tl3 are selected, after which the call signals are forwarded over these lines. At the same time, the call signals are temporarily registered in a control body in each of the stations B and D. For each call, which arrives at a station, e.g. B, it is checked by reading the aforementioned control body that the call has not already been received in the station. When a call now comes in over a line in group t3, the call is already registered in stations B and D, which is why the call is not forwarded. In the case of a backward signal, the most recently coated wire can already be released, which is however not necessary in the case of fast connection processes. At the same time, the call has been forwarded to station C over the line groups t4 and tl4 and to stations E and K over the line groups t5 and tl3, if free lines are found in said groups. In station C, when there are free lines, the same call comes in from two lines mostly simultaneously and is separated from each other by common devices, e.g. a marker, which only releases one link at a time. An answering device in station C scans the call signal and is affected while the signal indicates that station C is the called station. The response device sends a response signal to that line, e.g. a wire in the group t4, over which the call comes in first. This response signal is received in stations B and A, as the line groups t5, t3, resp. t2, which belongs to lines covered by the call, is released, while the lines belonging to line groups ti and t4, over which the answer signals are received, are retained and form a call connection between stations A and C. A downlink signal on the one in group t2 wire, release all wires connected to this wire in stations D, etc.

If there are no free lines in the groups t4 and tl4, the call is routed via stations E and K to stations C, H and F. If there is a free line in any of the groups t6 and tl5, e.g. in t6, this is selected, and the connection will be connected via stations B and K.

The station C is a main station in that in fig. 1 showed net. Calls originating from station C, e.g. to station H, can in unfortunate circumstances be connected via long detours, e.g. over stations F, E, D, B and K. The probability that such a detour will be used is, however, very small, while the cross-connection tl2, tl3, t3, t5, t7 is normally calculated for large blocking, while the inner cable groups t8 , tl6, tl5, tl4, t4, and t6 are intended for small blocking.

Fig. 2 shows an overview of the connection paths within a telephone station according to the invention. The cable bundles LNE and LNT constitute traffic routes from or to a local network. The lines TA, TB, TC, TD represent four roads with bidirectional traffic to stations outside the local network. Each line TA—TD and LNE has a relay set RA—RE with signaling device and a group selector device GA—GE. The relay sets RA—RE are arranged for regulating signals in both directions. The relay set RE is connected to the register SREG for outgoing traffic over a register seeker SS. The relay sets RA—RD and the registers SREG are connected to a common marker M via contact devices, which are designed in a known manner so that only one call at a time can be connected to the marker. Calls to the local set are connected via group selectors GV?1 which are connected to the local register LRÉG via the register searcher Rs.

The group selector devices GA—GE are made up of sub-selectors designated A—E within each group selector device. Each subselector corresponds to a traffic route. One of the conditions set for the group selector devices is that they must not be able to connect in the direction of traffic to which they belong. The easiest way to do this is to leave out the section selector, which corresponds to your own traffic route. The division into partial selectors is based on another condition for the group selector devices, namely that calls must be able to be connected simultaneously in all or at least several traffic directions and later disconnected independently of each other so that only one connection remains. The group selector GA can connect to the local network via sub-selector E and to the traffic routes or the cable groups TB—TD via sub-selectors

B—D.

The marker M receives call signals from the wires TA—TD and the register SREG, after which the marker sets the group selector GA—GE. The term call signal here includes all signals that are necessary to indicate a call to a certain station. Preferably, the call signals consist of at least one tone signal composed of several tones, which is connected to the connection's output line from the register SREG, which controls the connection's connection. The tone combination indicates at least the called station's number, remains on the connection's voice wires until a backward response signal is received and can serve as a call signal when connecting new lines. Of course, a special call pulse can precede the aforementioned tone signal, if the lines' relay equipment requires this, e.g. wires arranged for signals with direct current, 50-per. alternating current or inductive pulses. In the present invention, however, tone signals form the essentially essential call signal and are carried down into the station's marker M, while it affects recording devices P!—P5. Of these, Pl—P2 register a two-digit number indicating the called station, and P3—P4 a two-digit number indicating the calling station. The recording device P5 indicates one of a number of successive calls, originating from the calling station. This number need not be large, e.g. four. Since no more than ten different signal tones can be accommodated without practical difficulties in the speech band for a normal conversation channel for telephony, preferably five higher and five lower tone frequencies are selected, and two digits are sent simultaneously, one using the higher and one using the lower frequencies . The value of each digit is indicated by a combination of 2 or 3 simultaneous frequencies. If the digits for the called station's number are entered using combinations of two out of five tones and the digits for the calling station's number using three out of five tones, these numbers can be sent alternately with an intermediate pause calculated for return signals and a standing signal is obtained which can be read at the beginning anywhere after a pause. The pitch indicates the mutual order of two simultaneously transmitted digits and the number of tones in the combinations indicates called, resp. calling station. A separation of simultaneous calls between two stations by means of recording the order of the calls is only necessary for traffic between very large stations and can be carried out in several different ways, e.g. by means of switching between three types of tone combinations, namely with each two, three or four tones in each signal. Usually, the order of the calls can be specified in connection with the calling station's number, so that only an alternation between two types of tone combinations is necessary. The number of stations rarely exceeds 50 and the calling station's number does not affect the selector settings, but is only included to separate the calls and increase availability. If tone combinations with both three and four tones are used to mark the origin of calls, 25 is obtained. 15 = 225 combinations and each station can be assigned e.g. 3 to 6 combinations depending on the size of the station, which combinations are used in cyclic order to separate the calls in the network from each other. In the marker there is a multiple MR, a response device V, a number of control devices Ql—Qp and a selector MS for connecting these to the recording device Pl—P5. There is also a maneuvering relay set K.

The coupling device according to fig. 2 work in the following way. A call, which comes in e.g. via a wire TA is connected via connector a to the marker M. A tone signal on the wire sets in a manner known per se the registration devices Pl—P5, which indicate the number of the called station and the origin of the call. The call is designated in a multiple MR containing five groups of wires, some of which are connected to a current source via recording devices P1—P5. A number of control means Ql-Qp and a response device V monitor the registration in the multiple MR. If the registration contains the number of the station to which the marker M belongs, the answering device V is affected, and an answering signal is sent to the calling line TA. The maneuvering relay set is affected and the marker connects the wire TA across the partial selector GA—E to a local group selector GV. A local register LREG is switched on above the register seeker RS and the pointer M is freed. The continued connection process is completely conventional.

If the registration received in Pl—P5 is found in any of the control elements Ql—Qp, the maneuvering relay set k is affected so that the marker M is released without the group selector GA being affected. The line TA is blocked in anticipation of a disconnection signal.

If neither the response device V nor any of the control bodies Ql—Qp are affected, the selector MS seeks out a free control body, e.g. Q2 and transfers the call registration from Pl—P5 to Q2. At the same time, the marker M sets sub-selectors GA,— B, GA—C and GA—D to each free line TB, TC resp. TD, so that the calling wire TA is connected to these three wires simultaneously. If no free wire is found, e.g. in the group TD, however, TA is connected to the wires TB and TC while the partial selector GA—D as well as GA—E remain unaffected. The marker M is then released, but the control element Q2 remains set and marked busy for a short time, e.g. three seconds to monitor that the same call does not come in over any wire TB—TD. A response signal is then received, e.g. over the wire. TB, this is received in or transmitted from RB to relay set RA and causes subselectors RA—C and RA—D to reset while the connection between TA and TB over GA—B is maintained.

An outgoing call over a wire LNE causes the switching of a register SREG to the relay set RE by means of the register searcher SS. After the SREG has received the number of the called station, the marker M is switched on via a contact device k. The marker connects the line LNE with a free line in each outgoing traffic direction by setting the sub-selectors GE—A, GE—B, GE—C and GE—D to each free wire TA, TB, TC resp. TD. The marker is released and the register SREG connects a call signal to all the selected output lines via the relay set RE. This call signal indicates at least the called station's number as described above. When a response signal is received in the relay set RE over e.g. line TA, the connections across TB, TC and TD are disconnected by resetting sub-selectors GB—B, GE—C and GE—D.

The invention is particularly suitable for car telephone systems and fig. 3 shows how such a facility can be designed. The facility is thought to comprise a plurality of car telephone exchanges, each equipped with its own radio station and interconnected by means of groups of conversation channels, which form an arbitrarily designed network. Car telephone subscribers must be able to connect with any other subscriber, who is connected to the network directly or via the general telephone network, and must be able to be called without knowing the called car subscriber's location within the network.

For this purpose, there is a group selector device at each car phone exchange, by means of which a calling incoming call channel can be connected simultaneously with a call channel in every other group of call channels outgoing from the car phone exchange, as well as in each car phone exchange a search device that determines whether a call is directed to a subscriber , which can be reached from the radio station of the car telephone exchange and, if this is the case, sends a response signal to the calling call channel, as well as in each car telephone exchange control body which checks that the same call has not already been received in the car telephone exchange and signaling devices for each incoming call channel, which receives said answer signal and partly forwards the answer signal over the call channel to the nearest car telephone station in front, and partly causes the disconnection of all call channels connected to the call channel, outgoing from the station other than the one over which the answer signal is received. The connection process is characterized by the fact that connections are connected via all possible connection paths from a calling car phone exchange to the car phone exchange that can reach the called subscriber, in a search process, during which the latter car phone exchange is sought out with the help of a call signal, which indicates the called subscriber's number and successively is spread to all car phone exchanges in the network, after which a return signal from the searched car phone exchange indicates and selects the call channels in the connection path over which connection is first obtained, and all call channels not included in the connection path, which are covered during the search process, are released.

Each radio station within the car phone system has a station antenna and can reach the car phone subscribers who are within the range of the antenna. The antennas' range is assumed not to overlap. Each car phone subscriber has a radio antenna BN and a car phone equipment. Each station antenna AN constantly emits a number of carrier waves, which correspond to each call channel. Free call channels are marked from the station with a standing tone modulated in carrier wave. A car telephone equipment, which is connected and free, automatically tunes to a free call channel and is ready to receive a call signal from the station. Each call signal indicates the subscriber number of a called car telephone subscriber and is received and checked in all available car telephone equipment. The car phone, which is called, recognizes the call signal and assigns the call channel to which it is connected by means of an answer signal.

In fig. 3, AB is a car telephone equipment with an antenna BN. Each car exchange has a radio station F with a station antenna AN. The car phone switcher also includes searchers S and group selectors GV as well as a marker M and a number of registers REG with two register searchers RS and SS each. Common to the registers REG is a multiple MR with, in this case, three wire bundles designed to each mark a digit in a called car telephone subscriber's number. The car phone system is assumed here to be designed for a maximum of 1,000 cars and the car phone subscribers' numbers are three-digit. Groups of connection lines or conversation channels TA—TD connect the car phone exchange with other car phone exchanges and in particular incoming and outgoing lines LNT and LNF mediate traffic to and from the general telephone network. Calls originating from the car telephone exchange to other car telephone exchanges pass the group selector GV and special main lines TE. All lines TA—TE each have their own relay set RA—RE and each their own group selector device GA—GE made up of partial selectors A—E. In the register REG there are four digit magazines Pl, P2, P3, P4, a response device V, a control device Q and a relay device H. The register connects to the marker M via a contact device k, which is designed in such a way that only one register can be connected at a time the marker.

In the case of a call from a car phone subscriber AB, a signal is sent using a special tone frequency on the free call channel to which the subscriber's car phone equipment is set. The signal is received in the radio station equipment F, as the idle marking tone is disconnected and the call is connected via the searcher S and the register searcher RS to the register REG. The subscriber hears the answer tone and sends tone pulses for setting the register in a manner known per se. First, the telephone magazine Pl is set with tone pulses, which indicate whether the call is directed to a car telephone subscriber or to a subscriber in the general telephone network. In the latter case, the register connects immediately to the marker M via contact k. The group selector is set to a free wire LNF and the register and the marker are released. If the call is directed to a car telephone subscriber, the register waits for the signals which indicate the called car telephone subscriber's number and which are registered in the digit magazine P2—P4. The register then connects partly to the radio station equipment F and partly to the marker M. Under control of the registration in P2

—P4 broadcasts the radio station equipment F calls on all free call channels from the antenna An. If the called subscriber is found within AN's range, an answer signal is received on one of the radio station's call channels. The signal is transferred from the radio station equipment F to the answering device V in the register. The marker M is influenced and is made to set the group selector GV to the conversation channel in the equipment F, on which the response signal has been received. Then the register REG and the marker M are released. If the called car telephone subscriber is not within the range of the antenna AN, the answering device V is not affected and the marker sets the group selector GV to a main wire TE and connects this via sub-selectors GE —A, GE—B, GE—C resp. GE—D to a wire in each of the outgoing wire groups TA, TB, TC resp. TD. The cursor is released and the register REG connects a tone signal which, depending on the registration in the digit magazine P2-P3, emits a call signal on the lines TA-TD, indicating the called car telephone subscriber's number. When answers are received, e.g. over the line TA so that the called subscriber is reached, the relay set RE is affected and the non-required connections over TB, TC resp. TD is switched off by resetting the sub-selectors GE—B, GE—C and GE—D. The register REG is released. The subselector GE—A is retained.

Calls from the general network come in via the lines LNT and are connected to the register REG via the register searcher SS. The setting digit, which indicates that the call is set to a car phone subscriber, is in this case already registered in a station belonging to the general network. The register REG therefore only receives the car telephone subscriber's number, which is registered in the magazine P2—P4. The connection process is otherwise the same as for a call from an AB car phone subscriber.

A call that comes to a car exchange, e.g. across a wire TA, affects the wire's relay set so that the wire connects to a register REG across its register seeker SS. The call signals indicate the called party's number and are registered in the digit magazine P2—P4. The register is partly connected to the radio station equipment F

partly to the marker M by means of the contact device k. The call signal is sent via

you from the antenna AN and if an answer is received,

the answering device V is affected. The answering signal is repeated to the line TA and the marker is brought to connect the line TA via sub-selectors GA—E to the conversation channel in the radio station equipment F, over which the answer is obtained. If no response signal is received, check with the help of the control unit Q and the for all registers REG error-

read multiple MR, that calls to the same car phone subscriber are not already in the well-

geren. If this is the case, the regis-

teret REG and the station equipment F, and the calling line TA is blocked while waiting for the disconnection signal.

Calls to the requested subscriber are not found

nent previously registered in another register REG and no response is received within a certain time

from the radio station equipment F, together

butconnects the marker M the calling wire TA across subselectors GA—B, GA—

C, GA—D with a cord TB, a cord

TC and a wire TD, after which call

the signal is forwarded over these links

connections to all nearby car phone exchanges

learn to continue searching for the called subscriber. The marker1 M and the radio station equipment F are released, but the register REG is held back until the response signal, which

indicates that the sought car phone subscriber is reached, or the disconnection signal arrives at the relay set RA.

The call signal over the lines TA,

TB, TC and TD must indicate in this case a

three-digit subscriber number. In another case, a four-digit car telephone subscriber number may be required. The call sign must

despite this being a short signal, which can be quickly transmitted between the car phone exchanges.

Preferably, a tone signal is used together

composed of several frequencies. However, the number of tones must be kept down for both practical and economic reasons. For car telephones, the call is sufficiently specified by the requested car telephone subscriber's number, while never more than one connection can be made to each subscriber at a time. In order to

to reduce the number of necessary frequencies for tone signaling, it is suggested to combine

ner comprising alternating two and three of six tone frequencies. If two frequencies are selected

looking out of six, you get fifteen, combinations and selecting three frequencies out of six, you get twenty combinations. With two tone signal-

pulses in each call signal are obtained 300 num-

more. With three tone signal pulses is achieved

1500 numbers, if the first pulse includes

ter 15 combinations with two frequencies in each, the other 10 combinations of the 20 that could be obtained with three frequencies.

Using four tone signal pulses in each call signal, 500 numbers are obtained, if the first pulse uses any of five

tuned combinations with two tone frequencies

sees, the second some of the remaining 10 combinations with two frequencies, the third some of two specific combinations

ner with three frequencies and the fourth of the remaining two combinations with 10

frequencies.

In this case, it is assumed that the maximum

minimum 1000 subscriber numbers are required. Using five tone frequencies and three tone signal pulses per call signal, 1000 is obtained

number with only two frequencies. In order not to receive these in a specific order,

which had to be marked with a special

signal, e.g. a tone pulse with a sixth frequency, simultaneously occurring tone-

signals indicate the relative position of the digits in the subscriber number. At least two extra fre-

frequencies are needed for this, which is why seven tone frequencies are required. This sig-

nal system, however, provides simpler end and receiver devices than a signal system with six tone frequencies.

With five frequencies and three resp. four tone signal pulses in each response signal are obtained 500 resp. 2,500 numbers, and the first two

nepuls uses only one of the five fre-

quencies, the second a combination of two frequencies, the third a combination of three frequencies and the fourth which increases the number capacity from 500 to 2500 numbers

more, apply some of the possible combi-

nations obtained with four different simultaneously occurring frequencies.

Claims (4)

1. Automatic telephone exchange calculates network for telephone systems comprising several arbitrarily numbered stations in an arbitrarily designed network, intended to directly establish a call connection through the connecting path available for the occasion over the smallest number of stations between a calling and a called station, taking into account in part all alternative connecting paths through the network, partly from possible changes and blockages of traffic routes in the network, as the body in a calling station sends out a call signal that indicates at least the desired called station's number, and where each station contains devices (V) that determine whether an incoming call is routed to this station, and when this is the case sends a response signal backwards through the call channel (e.g. TA) through which the call comes, characterized by a common control body for the entire telephone station (Pl—P5, MR, Ql<<>—Qp) which registers and compares the call signals for all outgoing calls in the station at the same time and stops a call shout as long as a previous call with the same callsign exists in the station, and a group selector device (GA—GE) through which a calling, incoming call channel (e.g. e.g. TA) in a traffic path during a call directed to another station spreads the call signal to a free, outgoing call channel (TB, TC, TD) in each of all other non-blocked traffic paths outgoing from the station, as well as by signaling body (RA) that receives said answer signal, and partly forwards this backwards through the incoming call channel, partly causes the disconnection of all outgoing call channels selected by the group selector device for the propagation of the call signal except for the one through which the answer signal is received. 2. Automatic telephone exchange that an- , given in claim 1, characterized in that said call signal partly indicates the called station's number, partly the calling station's number and also the number of a switching device, e.g. a register (SREG) in the calling station. 3. Automatic telephone station as stated in claim 1, characterized in that said call signal consists of at least two alternating tone combinations selected from at least five tones, in that in a manner known per se the one tone combination contains two of these tones and indicates a first digit, while the second contains three of the tones and indicates a second digit, and that the number of tones in each tone combination indicates the order between two digits in a number indicated by the call signal. 4. Automatic telephone station as specified in claim 1 for car telephone systems with a majority each with its own radio station (F) equipped with a car telephone exchange (BV) and with an arbitrarily designed network containing groups per of call channels, which connect said car phone exchanges with each other, in order to establish a call connection to the subscriber from any other subscriber connected to the network, without knowledge of a car phone subscriber's location within the network, characterized by a group selector device at each car phone exchange, by means of which a calling, incoming call channel can be connected simultaneously with a free, outgoing call channel in each of all other groups of call channels outgoing from a car telephone exchange, paging arrangements in each car telephone exchange, which determine whether a call is directed to a subscriber, which can be reached from the car telephone exchange's radio station, and when this is the case sends a response signal to the calling call channel, in each car telephone exchange control body which checks that the same call has not already been received in the car telephone exchange, as well as for each incoming call channel signal body, which receives said response signal and partly forwards the response signal over p voice channels to the nearest car phone station, partly causing disconnection of all call channels connected to the call channel outgoing from the station except for the one over which the answer signal is received and interacting in such a way that connections are established over all possible connection paths from a calling car phone exchange to the car phone exchange that can reach the called subscriber, by a search process, during which the latter car phone exchange is sought out using a call signal, which indicates the called subscriber's number and which is successively spread to all car phone exchanges in the network, after which a return signal from the sought-after car phone exchange indicates the call channels in the connection path over which the connection is first obtained, and all incoming call channels not included in the connection well, which are covered during the search process, are released.