FI106833B - The connection method and the transceiver - Google Patents

Description

106833

Connection Method and Transceiver Technical Field

The invention relates to a connection establishment method 5 used in a cellular radio system using a TDMA multiple access method, comprising at least two transceivers, wherein connections between the transceivers are established by an information signal modulated on a carrier, and wherein the modulated carrier 10 is placed in a slot. li is transmitted on the carrier as a connection signal.

BACKGROUND OF THE INVENTION The invention is applicable to cellular radio systems, in particular GSM and DCS (Digital System for Mobile Communication) systems, which use TDMA (Time Division Multiple Access) technology. The multi-functionality is implemented 20 with multiple carriers and one carrier having, for example, eight users simultaneously. In order to distinguish between the signals of these eight users, they are transmitted in bursts at predetermined time intervals. That is, a certain transceiver: 25 transmits only at a specific time. Frame

• · I

'"I consists of these eight user time slots, and repeating this .1 frame allows the transfer of a large amount of data * ·« * ··:.

In the prior art, a subscriber terminal, for example, a mobile telephone, may have established a connection with, for example, a base station to which the subscriber has had the highest quality connection. Subscriber-.2 ·, the device has established a connection with one carrier «((• <. With the prior art solution, the resources of the different 35 time slots have been similar.

• · • · • «• · · * · · 1 · 1 · 2 • · 106833 2

For example, a known subscriber terminal could not have a voice connection to another subscriber terminal and communicate simultaneously with a data server, e.g., a high speed bit rate, such as a WWW server (WWW = World Wide Web). Essentially simultaneous connections in this case refer to connections in which bursts are transmitted, for example, within a time interval of the GSM system time slot since transmission of another connection burst.

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Characteristics of the Invention

It is therefore an object of the present invention to provide a solution for establishing simultaneous connections for the user, which may have different communication resources.

This is achieved by a method of the type disclosed in the introduction, which is characterized by establishing substantially simultaneous connections to the same or different transceivers by transmitting carriers in approximately 20 slots, and modulating information signals of successive slots on different carriers.

The invention further relates to a transceiver for use in a TDMA cellular radio system comprising at least two transceivers which communicate with one another through an information signal, the transceiver comprising modulation means, which modulate the information signal into a carrier, and transmission means that place the modulated carrier in a time slot and transmit the information signal into a modulated carrier as a connection signal.

·; ··· The transceiver is characterized by: * · *. the transmission means establishes substantially simultaneous connections to the same or different transceivers by transmitting the carriers in overlapping time slots, and the modulation means modulate the information signals of the successive time slots on different carriers.

The method and transceiver of the invention provide considerable advantages over the previous solutions. The method transmits and receives signals each modulated on its own carrier. Overlapping transmission and reception of signals is prevented by time synchronization of the signals and appropriate selection of time slots. It is possible for the user of the ti-10 wide terminal device according to the invention to communicate substantially simultaneously with several different objects. In addition, connections may have different resources. The foregoing means that, for example, a mobile phone user may be in a voice connection and substantially simultaneously, for example, in a data transmission connection operating at a high bit rate.

Explanation of the figures

In the following, the invention will be explained in more detail with reference to the accompanying drawings, in which Figure 1 is a block diagram illustrating the basic structure of a transceiver according to the invention, Figure 2 illustrates a cellular radio system employing the method signal.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 4 * 2 Fig. 1 illustrates the transmitter receiver according to the invention in substantial parts. More specifically, the figure shows the structure of a transceiver 100 which acts as a transceiver. The subscriber terminal can OL · 2 "... A as a cell phone subscriber terminal 100 treatment <(<from the reception side and the transmission side receiving side ... 35 comprises a receiving antenna 111, radio frequency parts 112, • 0 to 4 ·« • 4 • • 4 • 4 · er I c 2 «106833 4 demodulation means 113, decoder 114 and information source 115, which may be, for example, an earpiece.

The transmitting side comprises an information source 121, a coder 122, modulation means 123, radio frequency sections 124 5 and a transmitting antenna 125. The information source 121 may be, for example, a microphone. Further, the subscriber terminal 100 comprises control means 131 common to the receiving side and the transmitting side. In practice, the signal is transmitted and received by the same antenna. Further, the subscriber terminal 100 comprises signal reception means 116 and transmission means 126.

The receiving side of the subscriber terminal 100 of Figure 1 operates as follows. The radio frequency portions 112 of the subscriber terminal 100 transmit the RF analog 15 signal from the antenna 111 to the intermediate frequency and filter the signal. Radio frequency portions 112 also detect an intermediate frequency signal. Demodulation means 113 converts the broadband signal into a narrowband data signal. The data signal is appropriately decoded by decoder 114.

Decoder 114 typically decodes a convolution-encoded signal. Decoder 114 also typically decrypts and interleaves the pre-processed signal. The signal from the encoder 114 is further transmitted to the information source 25 on path 115. The signal received on the antenna 111 is also applied to the receiving means 116. The receiving means 116 receives a plurality of information signals contained in the carriers substantially simultaneously. The functions of the receiving means 116 are practically located in the demodulation means 113 and the radio frequency parts 112.

The transmitting side of the subscriber terminal 100 operates as follows. The information source 121 receives an audio signal.

Inputs and transmits a signal to the electrical equivalent encoder 122. The encoder 122 encodes convolutional code and typically encrypts 35 signals. In addition, encoder 122 interleaves the signal bits 5106833 or bit groups. The signal is then converted to radio frequency according to the prior art in radio frequency sections 124 and transmitted via antenna 125 to the radio path.

Transmitting means 126 transmits a plurality of information signals contained in the carriers 5 substantially simultaneously. The transmission facility 126 operations are in practice disposed modulating means 123 and the radio-frequency parts 124. The control means 131 control both the receiving side and the transmitting side activities, ίο subscriber terminal 100 transmitting means 126 DO-emitting different modulated carrier frequencies information signals, which are located slots, substantially simultaneously. The transmitting means 126 transmit only one slot at a time because simultaneous transmission of the slots is prevented. Simultaneous transmission of slots is prevented by synchronization. The receiving means 116 of the subscriber terminal 100 receive time slots modulated by several different carriers substantially simultaneously. Thus, the receiving means 116 preferably demodulates each of the 20 time-slots forming a connection on its own carrier. The radio frequency portions 112 are capable of handling the signal in the time slots because the simultaneous arrival of the time slots in the receiving means 116 is prevented. The blocking is practically implemented by time synchronization. j '\' Figure 2 shows a cellular radio system, if ''. The method of the invention is used. The cellular radio system comprises a plurality of subscriber terminals 100 and base stations 200, 201, 202. * · 'Kiosks act as transceivers. In the solution of FIG. 2, the subscriber terminal 100 communicates with the base station 200 via a signal 150. Signal 150 is comprised of time slots transmitted from time to time which:. , ···, comprise an information signal. The signal 150 is modulated before being transmitted to the carrier. The subscriber terminal 100 <35 also communicates with the base station 201 via signal 250 106833. For the user of the subscriber terminal 100, the connections made by the signal 150 and the signal 250 are substantially simultaneous. Transmission means 126 transmit signals 150, 250 modulated by their own carrier 5 waves. The modulated carriers may have different resources, whereby the carriers may carry a different amount of user information. The subscriber terminal 100 may also establish substantially simultaneous connections to, for example, the base station 200. The base station receives the signal transmitted by the subscriber terminal 100 and the base station's receiving means 116 demodulates the received signal. In practice, the receiving means 116 are disposed in the demodulation means 113. The base stations 200, 201, 202 and the subscriber terminal devices 100 are time synchronized so that the time slots do not overlap. In the embodiment shown in the figure, the base stations are synchronized, for example, by providing a synchronization signal to the base stations 200, 201, 202 via the PSTN network.

The subscriber terminals 100 are synchronized by the synchronization signals transmitted by the base stations. The signal 150 shown in the solution of Figure 2 may be, for example, a carrier of a GSM system. For example, signal 250 may be a carrier of a UMTS system (UMTS = Universal Mobile! 25 bile Telecommunication System).

". The subscriber terminal 100 shown in FIG. 2 is capable of establishing a plurality of connections, which are substantially simultaneous for the user, with different base stations • ·: 1 ··· 200, 201, 202. · · <! # ί ϊ 30 are modulated by carrier. It is possible for the subscriber terminal 100 to connect to the same base station with signals modulated by different channels. • If the connections made by the subscriber ···. 'wave modulated, then the benefits of various resources * 1 35 will not be realized.

• · • «• · · * · 1 V« »» * «7 106833

In FIG. 3, the subscriber terminal 100 transmits to the base station 200 at least two TDMA signals 1,2 with time slots containing information signals. Signals 1 and 2 can be transmitted to the same or batches on the tu-5 base station. In the solution shown in the figure, the subscriber terminal 100 transmits a signal in the time slots TS3 and TS7 of the TDMA signal. Further, the subscriber terminal 100 transmits a signal at time slots TS1 and TS5 of the TDMA signal.

The time slots are selected such that the time slots of the carrier 10 and the information signals modulated by the carrier of the same frequency do not overlap. The overlapping of time slots is prevented by appropriate time synchronization. Furthermore, in the solution of the figure, the signals TS1, TS5 of the slots TS3, TS7 of the TDMA signal 1 and the slots TS1, TS5 of the TDMA signal 2 are each modulated by its own carrier. Thus, the transmitting means 126 modulate each connection time slot on its own carrier. Carriers may have different resources, whereby carriers carry a different amount of user information.

Transmitting means 126 may establish substantially simultaneous connections to the same or different transceiver times by transmitting overlapping carriers in time slots.

·; The interleaving is preferably done such that the carrier frequencies used to modulate the successive: 25 time slot information signals differ. In addition, the modulation means 123 modulate the information formed by each connection on its own carrier before the in- 1 Modulation means 123 • · «'· *' 30 may jump carriers according to a predetermined frequency sequence. If carrier jumping is prevented, then modulation means 123 modulate carriers *** at a specific frequency.

The transceiver reception means 116 receive a substantially simultaneous output of information signals, each modulated by its own carrier. After receiving the information signal, the demodulation means 113 demodulates each connection information signal on its own carrier. Thanks to the interleaving of the carriers 5, the subscriber terminal 100 can transmit to the base station an information signal, modulated by a particular carrier, in a given time slot. In the next time slot, the subscriber terminal 100 may send to the same or batches of base stations an information signal modulated by another carrier.

While the invention has been described above with reference to the exemplary embodiments of the accompanying drawings, it is to be understood that the invention is not limited thereto, but can be modified in many ways within the scope of this inventive idea as set forth in the appended claims.

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Claims (21)

9 106833 A method of establishing a connection used in a cellular radio system using a TDMA multiple access method, comprising at least two transceivers, wherein connections between the transceivers are established by an information signal modulated to a carrier, and wherein the modulated carrier is placed in a slot, and a connection forming signal, characterized by establishing substantially simultaneous connections to the same or different transceivers by transmitting overlapping carriers in time slots, and modulating information signals of successive timeslots on different carriers. Method according to Claim 1, characterized in that the carriers are hopped according to a predetermined frequency sequence. 3. A method according to claim 1, characterized in that the carrier is transmitted at a specific frequency if carrier hopping is prevented. 4. A method according to claim 1, characterized in that, on its own carriers, the module I [·; · 1; the generated information signals are transmitted in the time domain at different times. • · · ·; ·. A method according to claim 1, characterized in that each information signal placed in the time slot is modulated by its own carrier. 6. A method as claimed in claim 1, characterized in that the carriers have different or similar communication resources. Method according to claim 1, characterized in that each information signal constituting the connection 106833, which is located in a time slot, in batches or on the same carrier frequency, is modulated. A method according to claim 1, characterized in that the signals to be transmitted are synchronized to prevent overlapping transmission and reception of modulated signals. 9. A method as claimed in claim 1, characterized in that the carriers are transmitted over time slots such that the frequencies of the carriers used in successive time slots are different. A transceiver for use in a TDMA cellular radio system comprising at least two transceivers that communicate with one another via 15 information signals, and which transceiver comprises modulation means (123) that modulate the information signal to a carrier, and transmission means (126). which place the modulated carrier in a time slot and transmit the information signal in the modulated 20 carrier as a connection signal, characterized in that the transmitting means (126) establishes substantially simultaneous connections to the same or different transceivers by transmitting the carriers overlapping time slots; ; time slot information signals on different carriers. ··· The transponder according to claim 10: ·. A receiver, characterized in that the transceiver comprises receiving means (116) which receive • · · 30 substantially simultaneously information signals, each modulated by its own carrier. Transceiver according to Claim 10, characterized in that the transceiver y <'; comprising demodulation means (113) for demodulating. 35 each of the connection information signals on its own carrier • 11 106833. A transceiver according to claim 10, characterized in that the modulation means (123) jumps the carriers according to a predetermined frequency sequence. A transceiver according to claim 10, characterized in that the transmitting means (126) transmits a carrier at a specific frequency if the hopping of the carriers according to a predetermined frequency sequence is prevented. A transceiver according to claim 10, characterized in that the transmission means (126) transmit information signals modulated by the modulation means (123) at different times in the time domain. A transceiver according to claim 10, characterized in that the modulation means (123) modulate the information signal contained in each time slot on its own carrier. A transceiver according to claim 10, characterized in that the transmitting means (126) overlaps the carriers in the time slots such that the frequencies of the carriers used for modulating the information signals of the successive time slots differ. I ( 18. A transceiver according to claim 10, characterized in that the transmission means ··· (126) transmit carriers with different transmission resources. Transceiver receiver according to claim 10, characterized in that the modulation means (123) each modulate the information signal placed in the time slot and forming the connection by a frequency difference or by the same frequency. •; .. j 20. The transponder according to claim 10 ···. 35, characterized in that the transmission means 106833 12 (126) time synchronize the information signals to be transmitted to prevent overlapping transmission and reception of modulated signals. A transceiver according to claim 10, characterized in that the transceiver is, for example, a base station or a subscriber terminal. • '* · • «· • *« · • «• • • ({• · ♦ • • • • • • • • • • • • • • M 10 • 10