FI57678C - MOBILRADIOANLAEGGNING - Google Patents

Description

ΓνΞ = 7) M (11) ADVERTISING / PUBLISHING - - '- löj trij utlAGGN, ngsskrift b ^ o / o • * • ^ 5 (45) FJ nt ri ^ ~ ^ (51) Kv.lk3 / lnt.CI. 3 H 04 Q 7 / 04- FINLAND-FINLAND (*) P * t * nttlhtk «mut - Ptttntarafikflini 3058/72 (22) H» k «ml * ptlvi - Anittlcnlngidt | 02.11.72 '' (23) Alkuplivl — GHtlghatsdif 02.11.72 (41) Become a publisher - Bilvlt offantilg 05.05.73

Patent and Registration Office .... ... ·.

_ *, / 44) Date of departure. -

Patent and registration documents in the field of publication and publication 30.05.80 (32) (33) (31) Pyydttty etuolkeui — Begird priorltet OU.11.71

Sweden-Sweden (SE) 14073/71 (71) Televerkets Centralförvaltning, Fack, S-123 86 Farsta, Sweden-Sweden (SE) (72) Ragnar Berglund, Farsta, Hans Östen Mäkitalo, Uttran, Knut Thorkel von Brömssen, Sollentuna, Sweden-Sverige (SE) (74) Oy Kolster Ab (54) Mobile radio equipment - Mobilradioanläggning This invention relates to car radio equipment which includes a number of main station units, such as car exchanges, which can be connected to a fixed telephone network and where each main unit has at least one main unit. at a connected base station with which to enable connections between the main unit and mobile units located in its coverage area, these mobile units can be accessed via a number of radio communication channels.

Since the present invention is intended for secret cases where it is desired to connect an arbitrary subscriber from a fixed telephone network to an arbitrary car subscriber and vice versa, it will be described in connection with this connection, which does not exclude the possibility of using it in other similar and similar connections.

In such car telephony systems, there is a desire that the system can be easily implemented to cover one or more states, that it may be possible to perform automatic call switching, that the system can be easily adapted to existing telephone arrangements, that the frequency band used in the system be highly usable. 57678 relationship that car units can be built with low transmitter power, that there is a possibility to maintain high call secrecy, etc. Another special feature of this system should be that the subscriber's fixed telephone network does not need to know the location of the mobile unit to which a connection is sought.

The object of the present invention is to provide a car radio system which fulfills these set requirements and which can be considered to be essentially characterized by the one presented in the apparatus according to the invention, which is apparent from the characterizing part of the following main claim.

A presently proposed embodiment of a car radio apparatus characterized by the features of the invention will now be described in more detail below with reference to the accompanying drawings, in which Figure 1 shows two car exchanges which, with respective base stations, each cover their own car telephony area, Figure 2 shows how nine can be divided into eighteen car telephone areas, Fig. 3 shows a continuous sweep pattern from the car service for a shared paging area to search for a paging channel, Fig. 4 shows a stepwise paging operation locking of the unit to a particular traffic channel, Figures 6a-6e show parts in frame stations and mobile units Fig. 7 schematically shows in more detail the connection of a particular piece of equipment in a car telephone exchange and its associated base stations.

In Fig. 1, reference numeral 1 shows a base station unit similar to a car exchange and associated with four trunk stations connected to the exchange, denoted 2-3 while the trunk stations are connected to the PBX by fixed cable connections 6, 7, 8 and 9, respectively. via cable connection 11. The area covered by the car telephone exchange 1 is symbolically shown in Fig. 1 as a rectangle 12, and the area within it is divided into four sub-areas, i.e. the base station area, each of which is served by its own base station. This car exchange 1 forms the car radio equipment together with the other car exchanges and each of these covers its own area. One such additional area is shown in Figure 5 57678 1 by reference numeral 13, which, like area 12, covers its own car telephone exchange with its four frame stations. However, the number of base stations is not limited to four, but can vary from 1 to practically applicable numbers, e.g. 15 · The number of car exchanges can thus be chosen so that a state-covering or multi-state network can be reached.

In the coverage area 12 of this car telephone exchange, there are not shown in the figure mobile units which can communicate with subscribers in a fixed network or can access the above via a number of radio channels available between the respective base stations and the mobile units in question and in addition via said cable connections. In this case, the system can be implemented in such a way that the mobile unit is normally connected to the frame station from which the highest field strength is obtained. Such a selection can take place in a manner known per se, so that the selection is performed in different stages with different sensitivities. The switching of the frame station is carried out automatically in the case where the mobile unit has moved from one area of the frame station to another and at the same time the connection becomes weak. In connection with the movement of this mobile unit from a certain area, e.g. from area 12 to the area adjacent to it, respectively, any connection made to the car telephone exchange for connection 13 is normally disconnected.

These car telephone areas form independent units and no central equipment common to a certain part or all of the areas present is thus necessary. The car telephone service is implemented in a specific frequency range with the required number of channels and. in the telephone network, the service is assigned to a specific number. These mobile units receive their own individual number from their own set of numbers. All calls are made in full duplex. The base stations are equipped with as many transmitters and receivers as are necessary to achieve the desired low level of busy in this system. Channel fetching takes place continuously over the entire range and no crystal control for channel cycle numbers occurs at car stations, Eddleen is conceivable that channel tones are variable on the trunk side so that transmitters and receivers that are not in use for calls automatically fetch an interference-free frequency range, which obviously brings better the use of the frequency band at the same time as lower equipment requirements in terms of harmful and unauthorized radiation, intermodulation and blocking.

The paging of a mobile subscriber in connection with a call from the network can be arranged either by always making the call via all call transmitters in state 4 57678 or by first making the call through the car telephone area where subscriber A is located and then, if the mobile unit does not answer, .

Information about the call is disseminated to car telephone areas via the state call channel, e.g. in a telecommunication channel system. This state-wide call must first contain the code of the mobile unit and partly information about where this call comes from. When the PBX receives the general call, the mobile unit code is sent on the local paging channel and stored in the PBX together with the call origination address, e.g. the area code. If the mobile unit answers, the A-subscriber's car exchange receives information on where the mobile unit is located and the free telephone line can be connected between the A-subscriber and the mobile subscriber's car exchanges, so that traffic selection can be implemented as in normal call forwarding.

Because a particular call is automatically transferred from one base station to another when crossing between the coverage areas of the base stations, the areas of the base stations can be formed relatively small without causing inconvenience. When using transmitter powers of the order of one or two watts, the range becomes about 10 km (450 MHz). This results in a high utilization of the frequency band because the same frequency can be used frequently. Low transmitter powers are also advantageous if portable stations are used and generally place lower demands on this equipment in terms of interfering noise from this transmitter and to prevent internal modulation at the receiver.

The degree of encryption of this system may not be complete, but using the above-mentioned variable channel frequencies combined with coded paging and automatic channel search would make improper side listening difficult. If it is desired to further increase the encryption, there is a possibility that the mobile unit will search for a new call channel at certain short intervals. In order to improve the quality of the call and increase the range, the mobile receiver can be equipped with two antennas and a switching system which automatically selects the antenna in question. case captures a better signal (antenna switching principle).

This thus achieves a certain number of radio channels within the frequency band allocated to the telephone service, of which one is used as a special paging channel and the other as a radio communication channel. The paging channel for car exchanges located close to each other is then set to separate frequencies in order to avoid mutual interference. All the paging channels of this car exchange are assigned a common beep, e.g. a 500 Hz tone, which is transmitted from all trunk stations and which allows mobile units in the coverage area of different car exchanges to locate different paging channels. In addition, each paging channel is provided with a first signal transmitted from a certain, defined base station, which is characteristic of the car exchange represented by that paging channel.

Figure 2 shows the preferred distribution of nine different first characters among 18 different areas, each of which (in the shape of a hexagon) is the coverage area of the car telephone exchange with its associated frame stations. Geographically distant areas may receive the same first sign.

These first characters then consist of sounds in the speech area.

As shown in Figure 5, a particular mobile unit retrieving a paging channel sweeps over the entire frequency band reserved for car telephone service. When this sweep reaches a radio channel, e.g. A, it is braked for a time that is so long that the receiver may determine whether this station is modulated with a common signal (500 Hz) or not. If this common signal does not exist on the channel in question (A), the scan continues to the next channel B and then to channels C, D and E. In Fig. 3, it is assumed that channel E transmits a common signal, whereby this mobile unit is locked to this voice (position).

When the mobile unit has found the paging channel on the basis of this common symbol, the first characteristic characteristic of the car exchange in whose area the mobile unit is currently located is retrieved. This search takes place, as shown in Figure 4, step by step between different audio frequency channels. This search is further performed by means of a specific bandpass filter hardware which automatically and stepwise examines these audio frequency channels, this filter arrangement being adapted to interrupt and stop the search when it finds the actual first character, i. in the case of the figure, the sound shown in the diagram by the number 7 · The reception of this first character is stored in the first memory element located in the mobile unit. In addition to this step-by-step search, means which, in the form of said bandpass filter arrangement, are also used to receive the second special token transmitted on the traffic unit assigned to the main unit and allocated to the main unit in proportion to this first mark. Said preparatory work for receiving the second character takes place in such a way that the filter arrangement is set according to the corresponding frequency of this second character 6 57678. In the case of the exemplary embodiment, the frequency for this second characteristic special character (local traffic tone) is selected to be twice the frequency of the local call tone (first character) in the same car telephone area.

Thus, if a mobile unit locked to a particular paging channel and prepared to receive another token receives its paging code from the base station, it immediately leaves the paging channel and now retrieves the traffic channel marked (second token) by the master unit. This call code is specific to this mobile unit and is stored in it in a specific second memory.

In the case of a re-search, the receiver of the mobile unit sweeps over the entire tape and when it finds a channel (station) marked with another character, the receiver is locked to this channel. The mobile unit then recalls the base station with its second code stored in memory. The frequency setting of the transmitter of this mobile unit is always changed according to the frequency of the receiver so that the duplexing distance is maintained therein. This code is sent three times per second throughout the call. When the base station in question receives the code (call) first transmitted from the mobile unit in question, this is stored in a third memory in this base station and when the mobile unit sends its call a second time, this is compared in comparative circuits with the contents of this memory. If these two calls are identical, as is the case, if the connection works smoothly, this station repeats the call of the mobile unit at the same time as the special characteristic second character (free tone) on the selected traffic channel then ends. With the help of this mobile unit's call code, the A subscriber can be connected to the correct channel in the trunk station within the area of the telephone exchange. Each time the trunk station receives a call from the mobile unit, this is repeated, and each time the mobile unit recovers its call, a certain time sweep circuit is set to zero, which determines how long the mobile unit is locked to the station. This can be seen in Figure 5, where points A ', B', D ', F' and G 'correspond to the times when the mobile unit has received its own call. At points C, E * and H ', the mobile unit has received a call back, but due to transmission interference, this code is incorrect. A certain point 1 'corresponds to a certain point in time when the mobile subscriber himself disconnects the call. This mobile unit then retrieves the paging channel as previously described. At point K ', about 1 second has elapsed since the mobile unit last received the correct code. The mobile unit now automatically leaves this frequency and searches for a new station marked with the same local traffic channel voice as the previous channel. When this mobile unit finds a new free traffic channel, the base station is called again, after which this new channel is closed from the other mobile units and the call is reconnected to the car exchange where the A-subscriber has been waiting for that time. This break should not normally last longer than about 1 second.

Figure 6 shows an example of what the codes used at base stations and mobile units may be. Fig. 6a shows the appearance of the code when it reaches the mobile unit or the frame station, respectively, while Fig. 6b shows how the incoming code character is converted into a square wave in a known manner. This converted code character is then compared with the information in the frame station in the corresponding memory and with the code character stored in the mobile unit (Fig. 6c), whereby these figures show that the converter character does not exactly match the stored character, e.g. The comparison takes place in the first reference circuit of the mobile unit not shown and respectively within the second reference circuit in the frame position by means of a certain reference mark (Fig. 6d) which recognizes the reference marks only within a certain predetermined time period so as to minimize the effects of said disturbances. If the entire code is accepted in the comparison, those circuits * correctly "generate a" pulse that causes the mobile unit or trunk station to transmit and reproduce a new code character, respectively, according to the diagram above.

In order to avoid that the comparison circuits accept an erroneous code mark because it instead recognizes e.g. the rest of the code of the second mobile unit (Fig. 6e), the structure of this code is such that the first pulse has a longer bit time than other bit pulses. bits of the same size left.

The comparison between the incoming call of the mobile unit and the code stored in the mobile unit takes place as on the paging channel.

Billing should be organized according to the principle that applies to ordinary calls, namely that subscriber A pays for the entire call, in which case this cost depends on the call time and the distance between the two subscribers in the call connection. If the A-subscriber is fixed, the above does not cause any problems. In order to perform correct billing in the event that the A-subscriber is mobile, all such calls are registered, e.g. by means of a perforated tape, in this car telephone exchange in the A-subscriber's car telephone area. This registration must therefore contain information on the number of this mobile unit, the call time and the location of the 8 57678 B-subscriber. At regular intervals, then, combine billing information from all the different car call centers in the state.

If several countries are included in the same car phone system, the number series must be common to these. If, for example, a subscriber from a certain state tries to contact a mobile subscriber in another state, he first takes the silent number of the other state, then the car telephone service number and lastly the individual number of the mobile unit. In the example according to the embodiment, this principle requires that the A-subscriber has information on the state in which the mobile B-subscriber is currently located.

In order to describe in more detail the different types of call connections, a number of traffic cases are described below with reference to Figure 7, which shows equipment in two car telephone areas X and Y. Area X corresponds to area code area 08 and area Y to area code area 063, where area X includes fixed subscriber Z, area code station 08 and car call center APK, which serves three trunk stations B ^, B2 and B ^, which together cover area X. Trunk station B ^ is shown in more detail and includes a local call channel with a transmission frequency of 450 mHz and N traffic channels with frequencies of 450 + N · 9.025 MHz. The frequencies of the receivers are located higher than 10 MHz. Furthermore, there is a mobile subscriber Mx in area X with a single number 79315 · Area Y contains the same hardware as area X. Area Y has a mobile subscriber My with subscriber number 27306.

When connecting a call between a fixed A-subscriber and a mobile B-subscriber within the same car telephone area, the fixed subscriber F 'first takes the number 20010, which indicates the car telephone service (the same number in the whole country). In this case, the F 'subscriber comes into contact with the car telephone exchange in the car telephone area in which he himself is located. When a free character is heard, the subscriber number of the searched subscriber is retrieved 79515 · This number is stored in the memory belonging to the car exchange at the same time as it is sent out via the paging channels at the base stations B ^, B2 and B ^. This call is transmitted with a simple phase shift at a modulation frequency of 400 Hz and a 3 * 2 kHz carrier. These paging channels is addressed in two different symbols in the above namely from one part to 500 Hz, which is common to call the character and the second character in accordance with the 700 Hz, which corresponds to the call sign that is above said first characters.

When the mobile subscriber Mx switched on its station, its receiver retrieved a 450-451 MHz station (paging channel) on the tape, which is modulated with a signal of 500 Hz. It is now assumed that this station found the trunk station B ^ on the frequency of the call transmitter 450,000 MHz.

9 57678 The hardware then retrieved the local call tone (first character) in area X, which it found at 700 Hz. This sound now locks the mobile unit Mx to the receiver's call channel. When Mx receives its paging code, it immediately leaves the paging channel and starts searching for a free traffic channel. These are modulated in the region X at a frequency of 1400 Hz = 2 * frequency for the local call tone (first character). Subscriber Mx finds this sound at 4-50.050 MHz it wants to say from channel 2 at trunk station B ^. If the mobile unit had been located in one of the frame stations and B2 in the area of influence, the correspondingly free channel would have been selected from there. The subscriber Mx now sends his own code (call) to channel 2 of the frame station B ^. This call is repeated three times a second as long as Mx is still on this frequency. The first call received at the trunk station is stored in a memory connected to the receiver on channel 2. When the subscriber Mx sends his call a second time, it charges the black content on channel 2. If there is a match, the second character (idle character) ceases and another channel is marked free connections between other subscribers. At the same time, channel 2 repeats the received code. This code, repeated by channel 2, is received in the device Mx and compared with its own code. If there is compatibility, a "correct" pulse is reached, which sets to zero the time sweep that keeps the device Mx on this channel. This scan time is e.g. 1 second, which means that the device Mx must receive its own code at least once every second during the call, from which it would not leave this channel. The Mx transmits its code throughout the call and the line 2 repeats the code each time it has received it correctly, i.e. the code of this mobile unit rotates between this mobile unit and the trunk station during an ongoing call during an out-of-band call situation). At the same time as the mobile unit receives the first "correct" pulse on this traffic channel, an acoustic signal is issued that a call is waiting. The mobile unit now transmits a response tone (e.g., a single tone from the audio range), in which case the loudspeaker and microphone, which were previously blocked, are turned on. On the trunk side, during this time, the car-telephone exchange has established a connection between subscriber A and channel 2 of the trunk station B, which means that the call has then been connected.

The base station must thus receive a call that is identical to that stored in the memory, e.g., at least once every two seconds, and the walking unit must retrieve its own call at least once every second during a particular call. If the field strength is low or this channel is disturbed, these suggestions will not be filled. The mobile unit then exits the channel, which is made available for possible vacancy marking. In this case, it can be mentioned that it is suitable for only one or a couple of channels to be marked free at a time. The mobile unit then retrieves the sound of the local traffic channel and can then only be locked to a specific channel in area X. The locking method is performed as above, after which the call is again connected to this car exchange. This break becomes on the order of 1 second. If the mobile unit does not find the local traffic channel sound, this search takes about 5 seconds and then returns to searching for the general call tone (standby situation), as a result of which the call is disconnected.

The established connection is disconnected when the A-subscriber drops the handset, whereupon the end signal is sent to the mobile unit, which automatically leaves the channel and retrieves the paging channel.

If, instead, the mobile unit terminates the call, the signal signal to the base station would run out, after which normal signaling is implemented in the telephone connection. The call is monitored by a voice-controlled time scanner in the mobile unit, which automatically disconnects after a certain time after the call has ended if this has not been done manually.

When the mobile unit becomes busy, its individual number is stored in the car exchange's memory, which is retrieved before the call is sent out from the new A-subscriber. The busy signal can thus be given as in normal telephone traffic.

In the event that the mobile unit receives the call but cannot find any channel that would be marked as free, the mobile unit returns to the paging channel where it sends its own code. The car call center can now send a busy tone to the calling subscriber.

In order to initiate a call between a mobile A-subscriber and a fixed B-subscriber within the same car telephone area, a mobile subscriber presses a dedicated body, whereupon this equipment retrieves a free traffic channel where it calls the trunk station with its own code. After this is connected to the car PBX, the mobile unit receives a free signal. Dialing is done with a series of push buttons. In this case, it is suitable for each number to correspond to a single voice in the area of the voice channel 11 57678, so that the same equipment used to search for paging and traffic channels can be used in this connection. When the base station receives a sound corresponding to a certain number, this is played. The mobile unit then receives confirmation that the number has been received correctly. The car exchange exchanges the fixed subscriber and the mobile unit receives the answer signal according to the normal telephone routine.

In order to establish a connection between a fixed A-subscriber and a mobile B-subscriber in different car telephone areas, a B-subscriber is first retrieved as described above. When the mobile unit does not answer in subscriber A's car telephone area, a state-wide search takes place. In this case, information on the area code of subscriber A and the individual number of the mobile subscriber is sent to all car telephone exchanges in the state. This information is sent through a special state call channel. When a particular car exchange receives a call through this channel, the mobile unit code and the A-subscriber's area code (or some other address information) are first stored in memory, after which the search is performed as described above using the mobile subscriber's single number. If the mobile unit is located within the car telephone area that is now in question and is responsible, the A-subscriber's telephone exchange will be notified, which will ensure that the free telephone line to the mobile subscriber telephone exchange is made available. This state-wide retrieval may, for example, occur twice at five-second intervals. If the mobile unit does not meet, the A-subscriber receives information about this ('e.g. a call notification).

The switching connection between mobile units in the same or different car phone areas takes place according to the same principle as above.

This system, with its local tones, means that calls cannot normally be transferred between different car phone ranges. If the mobile unit is located at the edge of a certain car kit phone at the beginning of a particular call and, moreover, moves away from it, the call may normally be dropped. This can simply be prevented, for example, by making the coverage area for paging channels in a certain car telephone area smaller than what the coverage area for traffic channels is. Because the mobile unit receives information about the voice of the traffic channel from this paging channel both in connection with its own call and from the base station, it can always travel a certain distance corresponding to the difference between the coverage areas of the paging channel and the traffic channel. This above can also be solved in such a way that the base stations in a certain car telephone area bordering on another area have the possibility to transmit the sound of the traffic channel of the latter car telephone area. This idle tone only needs to be transmitted when necessary and is preferably started when the car PBX in question indicates that a particular call is dropped.

If it is necessary to be able to transfer a certain call between different base stations in a certain car telephone area, it is suitable that there are fixedly connected wires between the car exchange and the base stations so that the transfer becomes sufficiently fast. If the traffic situation is so low that only one or a couple of traffic channels are needed, the paging channel can also be allowed to be a traffic channel. This channel must then be modulated with a common and local call tone as well as a local traffic channel tone.

As described above, the locking of the mobile unit normally takes place in the frame position within a certain defined area with the highest field strength. However, a mobile unit that is locked to a strong paging channel may, when moving, reach points where it is advantageous to change the paging channel. This mobile station must then be automatically arranged to search for a new paging channel at regular intervals. The probability that a mobile unit will be called during a handover becomes small because the paging time is short compared to the time between two different pagings. This latter time should be on the order of 1 minute. Besides, when each call is repeated at intervals of a few seconds, only a few calls may be lost due to the change of that call channel.

The present invention is not limited to the above exemplary embodiment, but modifications thereof may be made within the scope of the following claims.

Thus, for example, in order to achieve high call coverage, it may be advantageous to arrange this equipment in such a way that the mobile unit in question is regularly or irregularly forced to change the traffic channel at certain intervals during the connection of a particular call. Such a change of channel can be easily implemented by automatic or manual starts, which are performed e.g. by the above-mentioned time sweeping circuit.

Claims (20)

1. Mobile radio system which has a number of main station units, e.g. in the form of mobile telephone exchanges (1 in Fig. 1) connectable to the fixed telephone network, where each main unit has at least one base station connected to the main unit (2, 3, 3 or 5), with which, to enable connection establishments between the main unit and within its coverage area of mobile units, said mobile units may come into contact via a number of radio traffic channels, characterized in that each base station over a channel used for calling transmits one to the main unit, to which the base station in question is connected, specific signal and existing mobile units within the head unit's scope (12) read into the main unit via the base station by means of that signal, respectively. mobile unit exhibits a "memory screen" for storing the specific signal and means which, depending on that signal, prepares the mobile unit for receiving a traffic channel transmitted over a head unit free of charge and the main unit assigned specific second signal selected in relation to the first signal and that the resp. a mobile unit is also arranged to leave a call signal in the call channel caused by a connection connection in the call channel and search for and by means of the second signal read to the vacant marked traffic channel one. 2. Device according to claim 1, characterized in that mobile unit is also arranged to automatically copy over and read to a new from the main unit vacant marked traffic channel belonging to the same main unit by means of the stored first signal if the connection via the already engaged traffic channel is broken due to interruptions in the traffic channel, low field strength or the like. The mobile radio system of claim 1 or 2, wherein it utilizes a frequency band within which each main unit is assigned a particular call channel and said traffic channels and wherein the call channels for at least adjacent main units are assigned different frequencies, characterized in that all calls is assigned a common signal significant to the call channels, and that the mobile units within the coverage area of each head unit locate the head channel call channel by the common signal. h. A mobile radio system according to claim 1, 2 or 3, characterized in that each unit has two or more base stations connected to the unit, and that each mobile unit located within the coverage area of the main unit is designed to perform a call channel search in several stages where the sensitivity is 7 6 V 8 18 on the unit's receiver is increased in successive steps, thereby reading to base station with high field strength. A mobile radio system as claimed in any preceding claim, wherein it utilizes duplex connections, characterized in that the rep, mobile unit is assigned a specific code signal which, after reading the mobile unit to the vacant traffic channel by the second signal, is transmitted at intervals to the base station above said traffic channel, and in that case the base station is arranged to retransmit the received code signals to the mobile unit, whereby the mobile unit is read to the base station with the specific code signals after the second signal has ceased after the connection is connected. 6. A mobile radio system according to the claim eye-characterized thereof, that respectively. the mobile unit has a second memory where the code code specific to the mobile unit is stored, and the mobile unit also has first comparative circuits comparing the stored specific code signal with the code signals transmitted from the base station. Mobile radio system as claimed in claim 5 or 6, characterized in that, respectively. the base station has a third memory where an initially received code signal for the mobile unit is stored, the base station also has other comparative circuits where subsequent code signals from the mobile unit are compared with the stored code signal. Mobile radio system according to claim 5 ~ 7, characterized in that the mobile unit sends out its code signals at a predetermined interval, e.g. 3 gps per second, and that the base station ItersMnder the stored code signal each time an undistorted code signal is received. 9. A mobile radio system according to claim 6, 7 or 8, characterized in that, respectively. of the comparative circuits emit a right pulse or corresponding da consistency exists between the respective circuits. comparing code signals, and that the right pulse resets a time sweep, counts, etc. which is arranged to initiate channel change or disconnection of the connection if resetting does not occur after a predetermined time, e.g. 1-2 sec. Mobile radio system according to claim 9, characterized in that the mobile is arranged to automatically leave the traffic channel to which it has been read, as soon as the correct code signals have been missing for a predetermined time, e.g. 1 sec Mobile radio system according to any one of claims 5-10, characterized in that each of the respective radio stations. mobile unit specific code signal comprises a predetermined number of bits and in that the first bit is assigned a bit time exceeding the bit time of the other mutually equal bit signals.