SE468031B - PROCEDURES TO RECEIVE FROM A MOBILE STATION TO A RURAL MOBILE RADIO SYSTEM - Google Patents

Description

(3 10 15 20 25 30 CO É CN is designed to provide optimal properties from different points of view with It has thus technically been a relatively large freedom of choice in the design of the GSM system with respect to the system as such.

Instead of introducing a new independent digital cellular mobile radio system, such as the GSM system, in an area where there is already an analog cellular system, it has been proposed to introduce a digital cellular mobile radio system, which is designed to cooperate with the existing analog cellular mobile. the radio system. In order to obtain digital channels within the frequency band assigned to cellular mobile radio systems, it has been proposed to remove a number of the radio channels assigned to the existing analogue mobile radio system and use them in the digital cellular mobile radio system. Due to the proposed design of the digital mobile radio system, three or possibly six digital channels can record the same frequency band as a previous analogue radio channel by using time division multiplexing. Thus, the total number of channels can be increased by replacing some analog channels with digital channels in time multiplexes.

The intention is to gradually introduce the digital system and to increase the number of digital traffic channels, while the number of analog _traffic channels in the simultaneously existing cellular systems is reduced.

Analog mobile stations that are already in use will then be able to continue to use the remaining analogue traffic channels.

At the same time, new digital mobile stations will be able to use the new digital traffic channels. Dual-function mobile stations will be able to use both the remaining analogue traffic channels and the new digital traffic channels.

With the addition of the new digital traffic channels, a corresponding need arises for new digital control channels. The conventional duo mode systems in most cases use existing analog channels, such as specially assigned frequencies, as the control channel. However, the new all-digital systems will use digital control channels, which occupy TDMA time slots of the same type used for digital traffic channels.

Such digital control channels have previously been used in the European GSM system. In GSM, an access is always provided by means of a single burst to minimize the congestion of the channel allocated for access. Any subsequent measures such as authentication and encryption are performed on another type of control channel, which is assigned according to the access itself. This use of several types of control channels in GSM involves a significant complexity. For this reason, and in order to achieve better compatibility with the existing North American duo mode system, it is preferred to use only one type of uplink control channel for the fully digital system in the United States. A consequence of this decision is that the control channel used for access in the USA must also be able to handle functions other than access, such as authentication or encryption, which require more than one burst in a message. The present invention solves the particular problems associated with the use of multi-burst access messages.

SUMMARY OF THE INVENTION An object of the present invention is to provide a method which can be used by a mobile station for access to the terrestrial system via a digital control channel, taking into account that existing EIA / TIA-54 formats for digital traffic channels are to be used. with a minimum of modification for the digital control channel, in order to achieve a low complexity of the hardware in the mobile station. This is accomplished by using the same format for both the traffic channels and the control channels except that the traffic channel CDVCC and SACCH fields are used on the control channel to perform the structuring of the access to the terrestrial system from a mobile station.

A further object of the invention is to minimize the probability of collision between access messages, by arranging a reservation procedure for bursts following the first burst in an access message. This is achieved by including in the connection access bursts an information which tells whether another time slot should be reserved at a predetermined time to continue the access message or whether the burst in question was the last in the message.

A further object of the invention is to allow accesses with several showers, at the same time as the access time for accesses with only one shower is minimized. This is achieved by the mobile station in its first access burst including information on whether this is the last burst or whether more bursts will follow.

In the latter case, a shower is reserved after a predetermined interval, but several showers in between are left free for any other mobile stations that want access to the terrestrial system.

A further object of the invention is to provide an access method which makes it possible to use a full-speed channel or a half-speed channel as an access channel for a base station, depending on the traffic capacity required on the control channel. This is accomplished by uplinking time slots for multiscour access messages at intervals greater than one frame. As a result, the capacity (number of accesses per second) of a full-speed access channel is twice as large as the capacity of a half-speed channel, while the time required for an access message does not depend on whether the access channel has full speed or half speed.

A further object of the invention is to provide an access method with a small probability of causing multiple accesses, i.e. an access method that does not lead more than one base station to believe that it has been subjected to an access. This is achieved by using the digital verification color code DVCC when coding / decoding the cyclic redundancy check CRC in the same way as for the traffic channels. In other words, this "implicit" DVCC was still used, while the "explicit" DVCC (CDVCC field in the message) was used for the access procedure.

Both fields CDVCC and SACCH each have 12 bits, together 24 bits are uplinked, and 24 bits are used on the digital access channel to execute either of two possible patterns uplinked and either of two possible This achieves two things: firstly, it improves the uplink synchronization (essential for burst messages) and makes it easier to downlink distinguish between a control channel and a traffic channel by using the two standard 28-bit sync words. possible 24-bit patterns in the CDVCC-SACCH fields as sync words (the other (2 ** 24) -2 patterns are illegal) ï secondly, misinterpretations are practically ruled out by down-sending the messages "free" or "reserved" and uplink sends the messages "reserve" or "do not reserve" as one of the mentioned two possible 24-bit patterns.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 shows a part of a cellular mobile radio system with cells, a mobile exchange, base stations and mobile stations; Fig. 2 shows a block diagram of a mobile station used in accordance with the present invention: Fig. 3 shows a block diagram of a base station used in accordance with the present invention; Fig. 4A shows the frame structure of a radio channel as used in accordance with the present invention: Fig. 4B shows a time slot format for transmissions from a mobile station to a base or terrestrial station: Fig. 4C shows a time slot format for transmissions from a mobile station to a base or land station with a reservation field according to the present invention; Fig. 4D shows a time slot format for transmissions from a base or terrestrial station to a mobile station; Fig. 4E shows a time slot format for transmissions from a base or terrestrial station to a mobile station with two reservation fields according to the present invention; Fig. 5 shows an example of a radio channel frame with six time slots, in which control channels and traffic channels are mixed: Fig. 6A is a diagram showing the multiscour access method according to the present invention for the full speed mode; Fig. 6B is a similar diagram for the half-speed mode; Fig. 7 is a flow chart describing the access method of the present invention.

DETAILED DESCRIPTION OF THE DESIGNED EMBODIMENTS Fig. 1 shows ten cells C1-C10 in a cellular mobile radio system.

In reality, the method and devices of the present invention are applied in a cellular mobile radio system comprising many more cells than tic. To describe the invention, however, ten cells are considered sufficient.

For each cell C1-C10 there is an associated base station B1-B10 with the same number as the cell. Fig. 1 shows the base stations located near the center of the cell in question and provided with radiating antennas. However, the base stations for nearby cells may be located near the cell boundaries and have directional antennas, as is well known to those skilled in the art.

Fig. 1 also shows ten mobile stations M1-M10, which can move within a cell and from one cell to another cell. In reality, the method and devices of the present invention are applied to a cellular mobile radio system comprising many more than ten mobile stations. In particular, there are usually many more mobile stations than base stations. For the description of the present invention, however, ten mobile stations are considered sufficient. The system of Fig. 1 also includes a mobile exchange MSC. The mobile exchange is connected to all ten displayed base stations by means of cables. The mobile exchange is also connected, by means of cables, to a fixed public telephone network or a similar fixed network with ISDN facilities. All cables from the mobile exchange to the base stations and the cables to the fixed network are not shown.

In addition to the mobile exchange shown, there may also be other mobile exchanges connected by cables to other base stations than those shown in Fig. 1. Instead of cables, other devices can be used for communication between the base stations and the mobile exchange, for example fixed radio links.

The cellular mobile radio system shown in Fig. 1 comprises a plurality of radio channels for communication. The system is designed for analog information, such as speech, digitized analog information, digitized speech, and pure digital information.

According to the system, the term connection is used for a communication channel between a mobile station and a mobile station in the same system or another system, or a fixed telephone set or terminal in a fixed network, which is connected to the cellular mobile radio system. A connection can thus be defined as a call between two people who can talk to each other, but can also refer to a data communication channel, over which computers exchange data.

Fig. 2 shows an embodiment of a mobile station which can be used in a cellular telephone system operating according to the present invention. A speech encoder 101 converts the analog signal generated by a microphone into a bit data stream. The bit data stream is then divided into data packets according to the TDMA principle.

A fast associated control channel (FACCH) generator 102 generates control and monitoring signaling messages between the system and the mobile station and messages between the mobile station and the system. The FACCH message replaces a user frame (voice / data) when it is to be transmitted. A slow associated control channel (SACCH) generator 103 generates a continuous channel for the exchange of signaling messages between the base station and the mobile station and vice versa. A fixed number of bits, for example twelve, is assigned to SACCH for each time slot of the message train.

Channel encoders 104 are connected to the speech encoder 101, the FACCH generator 102 and the SACCH generator 103, respectively, for manipulating incoming data to perform error detection and correction. The techniques used by the channel encoders 104 are envelope coding, which protects important data bits in the speech code, and cyclic redundancy check (CRC), the perceptually significant bits in the speech encoder frame, for example twelve bits, being used to calculate a seven-bit control. A selector 105 is connected to the channel encoders 104 connected to the speech encoder 101 and the FAACH generator 102, respectively. The selector 105 is controlled by the microprocessor controller 130 so that at appropriate times user information over a specific speech channel can be replaced by system monitoring messages over FACCH. A two-shed interleaver or intersequencer 106 is connected. the voter's 105 output. Data to be transmitted by the mobile station is interleaved over two different time slots. The 260 data bits that make up a transmitted word are divided into two equal parts and assigned two consecutive time slots. In this way, the effects of RAYLEIGH fading are reduced. The output signal from the interleaver 106 is applied to the input of a modulo-two adder 107, so that the transmitted data is encrypted bit by bit by logical modulo-two addition of a pseudo-random bitstream.

The output of the channel encoder 104 connected to the SACCH generator 103 is connected to a 22-burst interleaver 108. The interleaver 108 interleaves the data transmitted over the SACCH over 22 time slots, each consisting of 12 bits of information. The interleaver 108 uses the diagonal principle, so that two SACCH messages are sent in parallel with the second message offset eleven bursts from the first message.

The mobile station further includes a sync word DVCC generator 109 for generating the appropriate sync word (sync word) and DVCC, which are to belong to a specific connection. The sync word is a 28-bit word used for time slot synchronization and identification. DVCC (digital verification color code) is an 8-bit code, which is sent by the base station to the mobile station and vice versa to ensure that the correct channel is decoded.

A burst generator 110 generates message bursts for transmission by the mobile station. The burst generator 110 is connected to the outputs of the modulo two adder 107, the 22 burst interleaver 108, the sync word / DVCC generator 109, degenerator 132, which generates channel coded control messages. A message burst including data (260 bits), SACCH (12 bits), sync word (28 bits), encoded DVCC (12 bits) and 12 delimiter equalizer 114 and a control channel message combiner, combined to a total of 324 bits, integrated according to the time slot format determined by the EIA / TIA IS-54 standard.

Under the control of the microprocessor, two different types of message bursts are generated by the burst generator 110: namely, control channel message bursts from the control channel message generator 132 and voice / traffic message bursts. The control channel message is generated in accordance with commands from the microprocessor 130 and is transmitted on a digital control channel with the same burst format as the traffic channel, but where the SACCH as well as the speech data normally generated in a speech / traffic burst is replaced by control information.

The emission of a burst equivalent to one time slot is synchronized with the emission of the other two time slots and is adjusted according to the timing provided by the equalizer 114. Due to the time spread, an adaptive conditioning method was used to improve the signal quality. For further information regarding adaptive conditioning techniques, reference is made to U.S. Patent Application Nos. 315, 561, filed February 27, 1989 and assigned to the same assignee. A correlator adapts to the rate of the received bitstream.

The base station is the master and the mobile station is the slave in terms of frame time. The equalizer 114 detects the incoming rate and synchronizes the burst generator 110. The equalizer 114 can also be used for checking the sync word and by the DVCC for identification purposes.

A 20ms frame counter 111 is connected to the burst generator 110 and so is the equalizer 114. The frame counter 111 updates an encryption code used by the mobile station every 20ms, once for each transmitted frame. It will be appreciated that according to the present specific example, three time slots form a frame. An encryption unit 112 is provided for generating the encryption code used by the mobile station. Advantageously, a pseudo-random algorithm was used. The encryption unit 112 is controlled by a key 113, which is unique to each subscriber. The encryption unit 112 consists of a sequencer, which updates the encryption code. The burst to be transmitted by the burst generator 110 is output to an RF modulator 122. The RF modulator 122 is arranged to modulate a carrier frequency according to the 1r / 4-DQPSK method (1r / 4-shifted). , differentially coded, 90 ° phase shift coding). The use of this technology means that the information is coded differentially, ie.

Z-bit symbols were emitted as four possible phase changes; in 1r / 4 and + 31r / 4. The transmitter carrier frequency delivered to the RF modulator 122 is generated by a transmission frequency synthesizer 124 in accordance with the selected transmission channel. Before the modulated carrier is transmitted via an antenna, it is amplified in a power amplifier 123. The carrier frequency RF power emission level is selected on the order of the microprocessor 130. The amplified signal passes through a timing switch 134 before reaching the antenna. The rate is synchronized to the transmission frequency by the microprocessor 130.

A receiver carrier frequency is generated depending on the selected reception channel by a reception frequency synthesizer 125. Incoming radio frequency signals are received by the receiver 126 and their strength is measured by means of a signal level meter 129. The value of the received signal strength is then transmitted to the RF. receives the receiver carrier frequency from the reception frequency synthesizer and the incoming radio frequency signal from the receiver 126, the sorority controller demodulates 130. the radio frequency carrier signal, so that an intermediate frequency signal is generated.

The intermediate frequency signal is then demodulated by an IF demodulator 128, which restores the original 1r / 4-DQPSK modulated digital information.

The restored digital information provided by the IF demodulator 128 is supplied to the equalizer 114. A symbol detector 115 converts the received two-bit symbol format of the digital data from the conditioner 114 into a one-bit data stream. The symbol detector 115 in turn generates three different output signals. Control channel messages are sent to a control message detector 133, which provides channel decoded and detected control channel information to the microprocessor controller 130. Any speech data / FACCH data is output to a modular two adder 107 and to a two-burst interleaver 116. By means of these components, the voice data is reconstructed. the data by assembling and rearranging information from two consecutive frames of the received data. The symbol detector 115 outputs SACCH data to a 22-burst interleaver 117. The 22-burst interleaver 117 reassembles and rearranges the SACCH data, which is spread over 22 consecutive frames.

The two-burst interleaver 116 outputs the speech data / FACCH data to two channel decoders 118. The convolutionally coded data is decoded using the inversion of the above-mentioned coding principle. The received cyclic redundancy check bits (CRCs) are checked to determine if any errors have occurred. The FACCH channel encoder further detects the difference between the voice channel and any FACCH information and directs the decoding accordingly. A speech decoder 119 processes the received speech data from the channel decoder 118 according to a speech decoding algorithm (VSELP) and generates the received speech signal. The analog signal is finally enhanced by filtering technology. Messages on the fast associated control channel are detected by the FACCH detector 120 and the information is transmitted to the microprocessor controller 130.

The output of the 22-burst interleaver 117 is provided to a separate channel decoder 118. Messages on the slow associated control channel are detected by the SACCH detector 121 and this information is transmitted to the microprocessor controller 130.

The microprocessor controller 130 controls the operation of the mobile station and the base station communication and also handles input and output data from the respective station. terminal key display unit 131. Decisions in the microprocessor control unit 130 are made in accordance with received messages and measurements taken. The key and screen unit 131 makes it possible to exchange information between the user and the base station.

Fig. 3 shows an embodiment of a base station which can be used in a cellular telephone system operating in accordance with the present invention. The base station comprises a plurality of component parts, which are substantially identical in design and function to the component parts of the mobile station shown in Fig. 2 and described in connection therewith. Such identical component parts 468 051 12 10 15 20 25 30 are in Fig. 3 provided with the same reference numerals as used above in the description of the mobile station, but differ from them by a prime sign (').

However, there are minor differences between the mobile stations and the base stations. The base station, for example, has two receiving antennas. For each of these receiving antennas, there is a receiver 126 ', an RF demodulator 127' and an IF demodulator 128 '. Furthermore, the base station does not include a keyboard and display unit 131 for the user as at the mobile station. Another difference is that the base station handles the connection with many mobile stations, as can be seen from the division into 3 channel handlers 1, 2, 3, each of which handles one of 3 time slots of one frequency.

When power is connected to the mobile station, the microprocessor controller 130 performs an initialization procedure. First, the auxiliary system parameters are retrieved, which means that the preferred system, for example wire line (B) or non-wire line, (A) is selected. Depending on the selection made, the scan of the control channels belonging to the preferred system starts.

The receive frequency synthesizer 125 is commanded by the microprocessor 130 to generate the frequency corresponding to the first assigned control channel. When the frequency is stable, the signal level meter 129 measures the signal strength and then the microprocessor 130 stores the signal strength value. The same procedure is performed for the frequencies corresponding to the other assigned control channels and the microprocessor 130 makes a ranking based on the signal strength for each frequency. The reception frequency synthesizer 125 is then ordered to tune to the frequency with the highest signal strength level, so that the mobile station will be able to try to synchronize to this channel.

The radio signal is picked up by the receiver 126 and demodulated in accordance with the selected carrier frequency of the RF modulator 127, after which it is demodulated by the IF demodulator 128. synchronization and primary analysis of the digital information in the radio signal is performed by the equalizer 114. If the equalizer 114 succeeds in detecting a sync generator 109, the equalizer 114 will be locked to the time slot belonging to that sync word. The mobile station waits for the system parameter administration message, which is decoded by the control channel message detector 133 and transmitted to the microprocessor 130. This message contains information about the system identity, protocol capability, the number of available search channels (PCs) and their specific frequency assignment.

In the event that the equalizer 114 cannot recognize the sync word within a prescribed period of time, the receive frequency synthesizer 25 is commanded by the microprocessor 130 to tune to the channel with the second strongest signal. If the mobile station is unable to synchronize in this second selection, the microprocessor 130 commands a change of the preferred system, for example from A to B or vice versa. Thereafter, the scanning of the assigned control channels for the new preferred system will begin.

When the mobile station has received the administration message of the system parameters, the search channels are scanned in the same way as the assigned control channels, ie. by measuring the signal strength and selecting the frequency with the strongest signal. synchronization to the paging channels is then performed accordingly.

After successfully synchronizing to a paging channel, the mobile station will leave the initialization procedure and start a sleep mode. The sleep mode is characterized by four states, which are controlled by the microprocessor 130 and which are run through in turn as long as no access to the system is initiated. It should be noted that the scanning of the paging channels is performed as soon as the bit error rate of the current paging channel increases above a certain level, in order to ensure that the mobile station listens to the paging channel with the largest signal strength.

The first state of the Sleep mode is a continuous update of the status of the mobile station, such as the number and location of existing access channels (AC). This information is transmitted to the mobile station in the system parameter administration message on the paging channel, called a digital forwarding channel (DFOCC). This message is decoded in the control channel message detector 133 and sent to the microprocessor 130. Some messages transmitted from the base station in the system parameters administration message require response actions from the mobile station, for example, a re-scan message will command the microprocessor 130 to restart the initialization procedure.

As another example, a registration identity message from the base station will force the mobile station to make a system access to register in accordance with the system access mode described below.

The second state of idle mode refers to the situation where the mobile station attempts to match paging messages sent by the base station. These mobile station control messages transmitted over the DFOCC are decoded in the control channel message detector 133 and analyzed by the microprocessor 130. If the decoded number matches the mobile station identification number, a connection to the base station will be established in the system access mode.

The third state in idle mode involves listening to orders sent by the base station over DFOCC. Decoded orders, such as an abbreviated alarm, will be processed by the mobile station accordingly. The fourth state of the sleep mode means that the microprocessor controller 130 monitors the input from the keyboard 131 for user activities, such as call initiation. When a call occurs, this causes the mobile station to leave idle mode and start the system access mode.

One of the primary measures in the mobile station's system access mode is that the mobile station generates an access message. The digital access channels (DACs) available for the mobile station, which were updated during idle mode, are now examined in a similar manner to the previously described measurement of the assigned control channels. A ranking for the signal strength of each channel is established, and the channel with the strongest signal is selected. The transmission frequency synthesizer 124 and the receive frequency synthesizer 125 are tuned accordingly, and a service request message is sent over the selected channel to inform the base station of the type of access, for example, call request, search response , registration request or order confirmation. After this message is completed, the amplifier 123 in the mobile station is turned off and the mobile station waits for further control messages on the DFOCC. Depending on the type of access, the mobile station will then receive an adequate message from the base station.

If the access type was outgoing call or search, the mobile station will be assigned a free traffic channel by the base station, and the mobile station will switch to the traffic channel and leave the system access mode. The mobile station will then tune the transmit frequency synthesizer 124 and the receive frequency synthesizer 125 to the frequencies belonging to the selected traffic channel. Then the equalizer 114 starts the synchronization. A time adjustment procedure is controlled by base stations: and is based on time delay measurements performed at the base station on the received signal. From this moment on, messages are exchanged between the base station and the mobile station over the fast associated control channel (FACCH) and the slow associated control channel (SACCH).

Messages from the microprocessor controller 130 are generated by the FACCH generator 102 or the SACCH generator 103 and data is error protected encoded in the channel encoder 104. The FACCH data is time multiplexed with speech data in the multiplexer 105 and interleaved over two bursts by the 2-burst interleaver 106. The data is then encrypted in the adder 107, which is controlled by the encryption algorithm generated by the encryption unit 112. The SACCH data is interleaved over 22 bursts by the 22 burst interleaver 108 and then output to the burst generator 110, where the SACCH data is mixed with speech data, FACCH data, the sync and DVC from the DVCLC generator 109. The RF modulator 122 modulates the bit pattern according to the n / -t-DQPSK principle. The power amplifier 123 is activated and the power level is controlled by the microprocessor 130 during the time of the transmitted time slot. 468 051 16 10 15 20 25 30 35 Control messages from the base station to the mobile station microprocessor 130 are also transmitted via FACCI-I and SACCH. The symbol pattern of a bit data stream is routed to the speech decoder 119, the FACCH detector 120 or the SACCH detector 121, depending on the type of data used. Speech data and FACCH data are decrypted by the modulo-2 adder 107 and the two-burst interleaver 116. The channel decoder 118 detects bit errors and informs the microprocessor controller 130 accordingly. The SACCH data is interleaved over 22 bursts of the 22-burst interleaver 117 before error detection is performed in the channel decoder 118.

Messages sent from the base station to the mobile station typically include alarm commands, requests for the channel quality measurement to be performed, disconnection calls and hand-off orders.

Messages sent in the opposite direction are those initiated by the users of the mobile station, for example the disconnection order. The latter order means that the user has finished the call, and the mobile station will leave control of the traffic channel and return to the initialization mode.

Figs. 4A, 43 and 4D show the structure of the digital channels according to the EIA / TIA standard IS-54. Fig. 4A illustrates the frame structure of a radio channel. According to this example, a radio channel frame typically consists of six time slots, containing a total of 1944 bits or 972 symbols. The frame has a length of 40 ms with a data transfer rate of 25 frames per second. Each time slot is typically numbered from 1 to 6, each comprising a 28-bit sync word as defined above.

Figs. 4B and 4D illustrate a time slot format for transmissions from the mobile station to the terrestrial station and from that The time slot format usually comprises 260 bits reserved for data transmission, the terrestrial station to the mobile station. 12 bits for a digital verification color code (DVCC), 12 bits for (SACCH), and 28 bits for synchronization and training data (SYNC). The time slot format a slow associated control channel from the mobile station to the terrestrial station includes two 6-bit blocks for information on protection time (G) and ramp time (R).

The time slot format from the terrestrial station to the mobile station includes a 12-bit block reserved for future use.

In a half-speed alternative, each half-speed speech / traffic channel uses a time slot in each frame. This means that one front comprises six half-speed traffic channels with time slots numbered in turn 1, 2, 3, 4, 5, 6. According to the full-speed alternative, each full-speed traffic channel uses two time slots with the same mutual distance in the frame, for example 1 and 4, 2 and 5, or 3 and 6. In this alternative, the time slots are numbered 1, 2, 3 and the configuration of a frame will therefore be 1, 2, 3, 1, 2, 3. It will be appreciated that for purposes of description, it will be assumed that the present invention utilizes the full speed alternative for the following examples.

To implement the present method of accessing the terrestrial system via the digital control channel, the format of the radio channels of Figs. 4B and 4D is changed as shown in Figs. 4C and 4E.

Fig. 4C shows the time slot format of the radio channel from a mobile station to a terrestrial station, when the channel is a digital control channel. In this case, there is no need for the slow associated control channel SACCH and the digital verification color code DVCC, as is the case if the radio channel is a traffic channel.

Instead, a reservation field RES of 12 + 12 = 24 bits is provided for transmitting information to the terrestrial station, as will be described in more detail in connection with Figs. 6A, 6B.

Fig. 4E shows the time slot format of the radio channel from a terrestrial station to a mobile station, when the radio channel is a digital control channel. As described above, there is no need for SACCH and DVCC. The 12-bit SACCH part is now a first 12-bit reservation field RES1 and the DVCC part is now a second 12-bit reservation field RES2 for transmitting information to the mobile station, as will be described in more detail in connection with Figs. 6A, 6B. . 468 051 18 10 15 20 25 30 Fig. 5 illustrates a Standardized frame, which includes both control channels and traffic channels. In this example, time slots 1 and 4 are used as control channels, while time slots 2, 3, 5 and 6 are used as traffic channels in the full speed mode of the system. In a half-speed mode of transmission, which will be described in connection with Fig. 6B, only time slot 1 in each frame is used as a control channel, while slots 2-6 are used as traffic channels.

The multi-shed access method according to the invention will now be described in more detail in connection with Fig. 6A for the full-speed mode of the mobile system.

The first row a) in Fig. 6A shows a number of frames F1, F2,. . ., each comprising 6 time slots 1-6. Since the transmission in this case takes place at full speed, the time slots 1 and 4 in each frame are control channels and may be free for the exchange of control information such as access messages, authentication messages, etc. The frame structure in row a) is the frame structure of the digital forward control channel DFOCC and the digital reverse control channel DRECC, indicating the time slots in a frame for these channels at a specific carrier frequency. Row b) in Fig. 6A shows the positions of the time slots of the digital reverse control channel DRECC, while line c) shows the positions of the time slots of the forward control channel DFOCC. The positions of the time slots for DRECC are the reference positions and coincide with the frame structure and the time slots according to row a). The DRECC time slots were used for uplink transmission (MS BS) and the DFOCC time slots were used for downlink transmission (BS MS). The time slots used for voice transmission are not shown.

The DFOCC time slots are offset for a certain time from the DRECC time slots, as determined due to signal strength measurements, a switching time from transmission mode to receive mode, and so on.

Initially, a mobile station may be in its sleep mode searching for any control data (information) bursts in the DFOCC time slots marked with "F" in Fig. 6A, line c). However, the present method is not limited to this mode of operation but can also be used when the mobile station performs the tasks in the subsequent access mode, as described above.

The base station thus sends a control message in the DFOCC time slots "F" and in RES1 and / or RES2, which message is addressed to a mobile station or to all mobile stations reading the DFOCC message on a particular DFOCC frequency channel, indicating that the time slot # 1 on this frequency (or on another frequency fz, f3,...) is free.

It is assumed that a certain mobile station MS1 has received the above-mentioned message that the time slot # 1 is free (arrow A1). This free time slot is thus reserved for the mobile station MS1 in the DRECC channel, i.e. when the mobile station MS1 wishes to transmit to the base station. The reserved time slot is marked with R in frame P4.

When the mobile station MS1 transmits in this reserved time slot (arrow A2), it also requests that the next time slot # 1 be reserved.

The base station only makes a note that this time slot # 1 is to be reserved and sends (arrow A3) any control message to the mobile station MS1. The time slot R in frame F7 is thus reserved for the mobile station MS1. There is a possibility that another mobile station MS2 has received the message about free time slot F in frame P2 on DFOCC but has a weaker signal strength as it transmits in time slot # 1, frame F4 to the base station. The mobile station MS1 with the stronger signal will "win" and a reservation of the time slot # 1 in frame _F7 is made for the mobile station MS1.

Thus, the base station only makes a reservation of the time slot # 1 in DRECC for the mobile station MS1, and the mobile station MS1 accepts the reserved time slot. Since in this example the mobile station wishes to send its control message during 3 time slots, it accepts the reserved time slots # 1 in frames F4, F7.

When the mobile station MS1 uses the reserved time slot # 1, frame F10, after receiving a control message (arrow A5) from the base station, it uses this reserved time slot for the last time, since the mobile station MS1 has used 3 time slots for control message including the last time slot. The mobile station MS1 10 15 20 25 30 G31 2 ° therefore responds by sending a message that the used time slot # 1 is now free, and sends its last control message in the reservation field RES (fig. 4C), arrow A6.

Fig. 6A also shows the case where another mobile station MS2 has gained access to the system via the base station but slightly later than what the mobile station MS1 did on the same carrier frequency fl. Since the time slot # 1 is assigned to the mobile station MS1, the mobile station MS2 is assigned the time slot # 4 in the same frame. This mobile station is assumed to make a Z-burst access to the base station. The same procedure B2, the base station sends its control message, arrow B3, to the mobile station is initiated as for the mobile station MS1, arrows B1, but then the station MS2, it will answer that it will not need more time slots # 1 (in addition to its control information). The mobile station MS2 therefore sends a message, arrow B4, to the base station that this time slot # 4 may be free.

As shown in Fig. 6A, time slot # 1 is used in every fourth frame of the mobile station MS1, while time slot # 4 in every fourth frame is used by the mobile station MS2. Thus, time slots # 1 and # 4 are empty in two intermediate frames. These time slots can be accessed by other mobile stations. It can also be observed that the mobile station itself decides whether it needs more time slots for access or whether subsequent time slots can be left vacant by the base station. This means that the probability of collision between access messages from mobile stations to the base station (ie to the system) is minimized.

The access procedure of the present invention can also be used for a half-speed channel as an access channel. Fig. 6B shows such a case, where only one time slot in each frame was used for multiscour accesses. 6B, the mobile station MS1 finds a message in the downlink time slot in the second frame and a reservation is made in Fig. The base station of the mobile station MS1 in this time slot, arrow A1. The subsequent procedure according to the arrows A2-A6 is the same as for the mobile station MSI in the full-speed mode described in Fig. 6A and this also applies to the mobile stations N82, MS3.

Fig. 7 is a flow chart describing the various steps taken in the mobile station and in the base station for carrying out the method of the present invention.

In block 701, a mobile station of a plurality of such is in its idle state and receives data messages from the system via a base station on the digital control channel (DFOCC) in time slots, each having the format shown in Fig. 4E. These messages are addressed to individual mobile stations or to all mobile stations that can read this specific DFOCC.

Messages addressed to all mobile stations, ie. mass messages, contains information about the system and information that governs the actions taken by the mobile stations during system access.

In block 702, there is a need for system access for a mobile station. The reason may be a response to a search or a response to a change in system information, such as registration control data, or that the mobile station's subscriber wishes to make an outgoing access.

In block 703, the mobile station initiates its access by reading the reservation field RES1 or RES2 in a burst of DFOCC from the base station (arrow A1 in Fig. 6A). The value of the field is detected and it is examined in MS whether this value is indicated as reserved or vacant by the base station, block 704. If the RES1, RES2 value of the reservation field indicates that the time slot is reserved for another mobile station, the process is transferred to block 705 in the mobile station. If, on the other hand, the RESI reservation field, RES2, indicates that the time slot is not reserved ("free"), the process proceeds to block 706.

In block 705, a reserved time slot of the mobile station is found.

The number N of this type is maximized (without entering block 706). If the maximum number N is exceeded ("yes", block 705), then the process is aborted and returns to block 701. On the other hand, if the maximum number N is not exceeded ("no", block 705) then 468 031 22 10 15 The process returns to block 703 after a random delay.

In block 706, the mobile station uses the time slot indicated by the base station as free, by starting the transmitter and transmitting the first burst in the access message (arrow A2, Fig. 6A).

In block 706A, the mobile station examines whether the access message contains more bursts to be sent to the base station, and the RES field in DRECC is marked reserved, after which the process proceeds to block 707.

If, on the other hand, it was the last burst in the access message, the transmitted burst is read only by the base station and the RES is set free, each process returns to block 701 while the mobile station waits for the system to respond, block 706B.

In block 707, the base station in the system reads the burst transmitted by the mobile station (arrow A2, Fig. 6A). The system checks the validity of the data word included in the cut and detects the contents of the received reservation field RES. If the data word turns out to be correct (checksum OK) and the reservation field indicates reservation, the system sets the corresponding reservation field RES1, RES2 in DFOCC to be "reserved".

In block 708, the mobile station (arrow A3) receives and reads the reservation field RES1, RES2 set by the system. The message received from the base station is examined, block 709. If the mobile station in block 709 finds a reservation in the fields RES1, RES2, the mobile station can continue with the access and the process is returned to block 706 for transmission of the next burst. On the other hand, if a free indication is detected, the process is transferred to block 710.

Block 710 detects a failure. The number of times this type of failure occurs is maximized. If the maximum number N has been exceeded, the process is interrupted and returns to block 701. Blocks 706B and 707 are executed in the base station by the microprocessor 130 ', which is activated by a signal from the control channel message detector 133' to read the reservation field RES. Thereafter, the microprocessor 130 'activates the control channel message generator 132' to send a control message to the mobile station MSI in the reserved time slot. The microprocessor 130 'also sets time slot # 1 either to be a reserved time slot (block 707) or to be a free time slot (706B).

The other function blocks in Fig. 7 are performed in the mobile station MS1 by the microprocessor 130 (Fig. 2). The microprocessor 130 is activated by the control channel message detector 133 to read the control message and the reservation fields RES1, RES2 and to activate the control channel message generator 132 to send the control message to the base station.

Claims (10)

468 031 24 10 15 20 25 30 PATENT REQUIREMENTS A method for accessing a terrestrial mobile radio system from one of a plurality of mobile stations, which communicates with the terrestrial system in time slots (TDMA) and which can access a base station in the system by means of an access message over a digital control channel, characterized in that a mobile station (MS1) obtains access to a base station (BS) in the system by sending to the base station over said control channel (CC) a reservation (RES) of a number of time slots, each with a given location (# 1) within a frame (F4, F7, F10) to be reserved in said base station (BS) for said mobile station (MS1) for the mobile station to complete an access message over said digital control channel in the reserved time slots. Method according to claim 1, characterized in that said base station transmits control data messages in a number of time slots (1, 4) in a frame (F1, P2,...) Which is smaller than the total number of time slots (1-6). ) in the framework, said control data messages being directed to different mobile stations (MSI, MS2,...) in the system, that said mobile station (MS1) in a idle state listens for control data message and makes an attempt to send such control data message to the base station (BS) together with an indication that the specific time slot (# 1) in the frame (F4), on which the control data message from the base station was sent to the mobile station, is to be reserved for the next control data message from the mobile station to the base station. Method according to claim 2, characterized in that, if said mobile station (MS1) has succeeded in an attempt to access said base station (BS) in said attempt to access the base station, a certain time slot (1, F4) is reserved. for this mobile station (MS1), and that the base station sends its control message to said mobile station (MS1), which after receiving this control message sends its control message in said reserved time slot (1, F7) to the base station (BS). Characterized by the mobile station for which said time slot has been reserved, Method according to claims 2-3, sends a last data control message receiving said reserved time slot (# 1), then it simultaneously sends a message that the reserved time slot (# 1) is to be made available in the base station (BS). Method according to claim 1, characterized in that said data control message (D) over said digital control channel (CC), which is transmitted from said base station (BS), occupies a reservation field (RES1, RES2), which is left vacant in a certain time slot. (# 1 or # 4), when used as a digital control channel (CC) instead of a traffic channel (TC). Method according to claim 5, characterized in that said reservation field consists of two field parts (RES1, RES2) in the time slot used as a digital control channel (CC), said field parts corresponding to a slow associated control channel (SACCH) and a digital verification color code (DVCC), when used as a traffic channel (Tc). Method according to claim 1, characterized in that said data control message (D) over said digital control channel (CC), which is transmitted from a mobile station (N81, MS2, ...) to a base station (BS), occupies a reservation field ( RES), which corresponds to the fields occupied by a slow associated control channel (SACCH) and a digital verification color code (DVCC) in a traffic channel (TC). Method according to claim 1, characterized in that the specific time slot (# 1) in a certain frame (F4), which has been reserved in the base station (BS) for a certain mobile station (MS1), is reserved in the same time slot (# 1 ) and in a frame (F7) a predetermined number of frame intervals (F5-F6) after the frame (F4) for the first reserved time slot (# 1), whereby a number of frames are left with empty time slots for access from other mobile stations (MS2, MSS) . Method according to claims 1-4, characterized in that two different time slots (# 1, # 4) in each frame (F1, F2, ...) can be accessed, read C1 \ C10 and reserved for two different mobile stations ( MS1, MS2), when the system is operating in full speed mode. Method according to claims 1-4, characterized in that only one time slot (# 1) in each frame (F1, F2,...) Can be accessed and reserved for only one mobile station (MSI), when the system operates in a half speed mode. m1