JP2001521699A - Channel selection method in GSM / DCS based cellular wireless network - Google Patents

Abstract

SUMMARY The present invention relates to physical channel selection in GSM / DCS based cellular wireless networks. More particularly, the invention relates to the selection of fixed physical control channels and the selection of physical traffic channels. The base station (100) contains a list of physical channels allowed for the base station (100). In this method, the interference level of the allowed physical channel is measured, and the physical channel to be used as the radio link (108) is selected based on the measured interference level. The base station (100) selects the channel with the lowest interference level as a fixed physical control channel from the allowed physical channels measured by the base station (100). Based on the status, the subscriber terminal (104) and possibly the base station (100) select a physical traffic channel. A physical channel located at a fixed frequency interval from the downlink of the selected physical traffic channel is selected as the physical traffic channel uplink. Alternatively, the frequency spacing between the downlink and uplink of the selected physical traffic channel is of random size.

Description

Description: A channel selection method in a GSM / DCS based cellular radio network Field of the invention The present invention relates to physical channel selection in GSM / DCS based cellular wireless networks. More particularly, the invention relates to the selection of fixed physical control channels and the selection of physical traffic channels. Description of the prior art One significant problem is the limited amount of radio spectrum available for the development of cellular radio networks. Attempts have been made to minimize interference caused by co-channel and adjacent channel signals by carefully planning the use of radio frequencies. The coverage area or cell of the base station is typically modeled as a hexagonal area. The hexagons are arranged to overlap each other. The frequency is divided into individual cells based on different types of complex models. Its purpose is to maximize the capacity of the network by minimizing the interference that occurs on the wireless connection. In this regard, the concept of "frequency reuse factor" is taken. In principle, the lower the reuse factor, the more efficient the use of the frequency range. On the other hand, the same or adjacent frequencies cannot be brought close to each other in the cell reuse pattern. This is because severe interference occurs in the system. In GSM / DCS based cellular wireless networks, frequency planning is performed manually. At this time, planning is performed to use the frequency band available to the network operator most efficiently. Frequency planning is performed in advance when planning the network. During commissioning, the results of the frequency planning must be checked, for example, by measuring the coverage of base stations to be performed in the region. This is because it is very difficult to model the propagation of radio waves theoretically and it is not possible to form a completely reliable frequency plan only with theoretical calculations and planning. In particular, reflections on radio signals from different terrains and buildings make planning cell coverage difficult. When commissioning a network, frequency planning and measurement must be performed to expand the coverage area of the network and increase the capacity of the network. Manual network planning and associated measurements are expensive, but have so far been economical in densely populated countries and cities due to the relatively low user penetration of cellular wireless networks. As the use of mobile phones and other subscriber terminals becomes more prevalent, the capacity of the network must continue to increase. This leads to high costs in the form of different types of frequency planning and measurement. To increase capacity, microcells and picocells must be introduced. Frequency planning is more and more difficult than ever. Particularly in office buildings, the problem arises that different types of building materials cause interference in the propagation of radio waves. A new method for frequency planning of such problematic objects has been developed. However, costly measurements are required to ensure the working capacity of the system. On the other hand, too high a frequency reuse factor is costly in that capacity is lost. In conclusion, current GSM / DCS based cellular wireless networks require careful frequency planning and may be slightly more costly to ensure the working capacity of the system. Summary of the Invention It is an object of the present invention to provide a method that solves the above problem. This is a method of performing physical channel selection in a GSM / DCS based cellular wireless network, the cellular wireless network comprising at least one base station and at least one base station connected to the base station by a two-way radio link. Two subscriber terminals, the two-way radio link comprising: at least one fixed physical control channel downlink and at least one fixed physical control channel uplink; and at least one physical traffic channel downlink and at least one One physical traffic channel uplink, wherein a logical channel is arranged on the physical channel, and the base station communicates the physical channels allowed for the base station. It includes a list of channel, to measure the interference level of the allowed physical channels, and is achieved by a method of selecting on the basis of a physical channel to be used as a wireless link to the measured interference level. A first method according to the invention is characterized in that the base station selects the channel with the lowest interference level as the fixed physical control channel from the allowed physical channels measured by the base station. A second method according to the invention is characterized in that a physical channel located at a fixed frequency interval distance from a downlink of the selected physical traffic channel is selected as an uplink of the physical traffic channel. A third method according to the invention is characterized in that the frequency spacing between the downlink of the physical traffic channel used as the radio link and the uplink of the physical traffic channel is of random size. Another object of the present invention is a system for performing physical channel selection in a GSM / DCS based cellular radio system, the cellular radio network comprising at least one base station and a bidirectional radio link to the base station. Connected at least one subscriber terminal, the two-way radio link comprising at least one fixed physical control channel downlink and at least one fixed physical control channel uplink and at least one physical traffic channel A downlink channel and at least one physical traffic channel uplink, wherein a logical channel is located on said physical channel and a base station is allowed for said base station. The base station and / or the subscriber terminal are configured to maintain a list of physical channels, and the base station is configured to measure an interference level of the allowed physical channel, and the base station is configured as a wireless link. It is to provide a system configured to select a physical channel to be used based on its measured interference level. A first system according to the invention is characterized in that the base station is arranged to select a channel with the lowest interference level as a fixed physical control channel from the allowed physical channels measured by the base station. I do. A second system according to the present invention is configured such that the base station selects a physical channel located a fixed frequency interval from the downlink of the selected physical traffic channel as an uplink of the physical traffic channel. It is characterized by the following. A third system according to the invention is characterized in that the frequency spacing between the downlink of the physical traffic channel used as a radio link and the uplink of the physical traffic channel is of random size. Numerous effects are achieved by the method of the present invention. A very significant effect is that frequency planning is completely avoided. Another significant advantage is that network capacity is increased by efficient reuse of frequencies achieved by effective channel selection. Network capacity is also increased by the ability to cost-effectively deploy microcells and picocells. The present invention is capable of implementing a GSM / CDS based office system with high market expectations. The system of the present invention has the same effect as above. The preferred and detailed embodiments can be combined in different types of combinations to give the desired technical effect. BRIEF DESCRIPTION OF THE FIGURES Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. FIG. 1 is a diagram illustrating a cellular wireless network. FIG. 2 is a diagram illustrating a physical channel of a radio link and a logical channel to be moved on the physical channel. FIG. 3 is a block diagram illustrating the structure of the base station and the base station controller. FIG. 4 is a block diagram illustrating the structure of the subscriber terminal. Detailed Description of the Preferred Embodiment The invention is applicable to all GSM / DCS based cellular wireless networks. GSM / DCS-based cellular radio networks include Pan-European GSM systems in all different stages of development, namely Phases 1, 2 and 2+; DCS1800 and DCS1900 systems developed based on GSM systems; And new development projects based on them, for example, a UMTS system under development for those partially based on the GSM system. Here, a GSM system is used as an example, but the present invention is not limited to this. FIG. 1 is a diagram illustrating the structure of a cellular wireless network according to the present invention. The base stations 100, 102 have a hexagonal coverage area or cell. The base stations 100, 102 are possibly connected to a base station controller 114 via a connection line 112. The role of base station controller 114 is to control the operation of multiple base stations 100,102. Typically, there is a connection from the base station controller 114 to the mobile telephone switch 116, which in turn has a connection to the public switched telephone network 118. In an office system, in addition to the base station 100, the base station controller 114, the operation of the mobile telephone switch 116 can be combined in one device, which is then connected to a public switched telephone network 118, for example. , Connected to the telephone exchange of the public switched telephone network 118. The subscriber terminals 104, 106 of the cell have two-way radio links 108, 110 to the base station 100 of the cell. Further, the network part, the fixed part of the cellular wireless network, may comprise more base stations, base station controllers, transmission systems and network management systems at different levels. As will be apparent to those skilled in the art, a cellular wireless network also includes many other structures, which need not be described in detail here. The two-way wireless link 108 is implemented by using physical channels. The physical channel is, for example, one time slot in the 200 kHz frequency band in GSM. FIG. 2 briefly illustrates the channels required for the wireless link 102. The vertical axis shows the frequency range of the GSM system, the base station 100 is shown on the left of the figure and the subscriber terminal 104 is shown on the right. The lower frequency band 212 is used for the uplink, that is, for the uplink from the subscriber terminal 104 to the base station 100. In GSM, the low weekly multiple band 212 comprises the frequency range of 890 to 915 MHz. High frequency band 210 is used for the downlink, that is, for the downlink from base station 100 to subscriber terminal 104. The network operator allocates only a predetermined part of the frequency band, for example, dividing the 5 MHz frequency band into 200 kHz carriers, each of which usually consists of eight time slots. Here, a time slot is referred to as a physical channel. For example, in transmitting speech, two physical channels are typically used as traffic channels, one of which is downlink channel 202 and one of which is uplink channel 206. When the new standard is completed between 1997 and 1998, a number of physical channels can be used simultaneously, for example for data transmission or for the transmission of moving picture images. As can be seen from FIG. 2, a logical traffic channel TCH is arranged in the uplink and downlink physical traffic channels 202, 206. This logical traffic channel TCH can, if necessary, be completely or partially replaced by the fast associated control channel FACCH associated with the traffic channel. In addition, the establishment and connection of the connection requires both separate fixed physical control channels, the fixed physical control channel 200 downlink and the fixed physical control channel 202 uplink. "Fixed" means that the fixed control channel is always transmitted on the same frequency and the same time slot, and that the fixed control channel is not committed to individual calls (eg, like DECT). The physical control channel downlinks are a broadcast control channel BCCH, a frequency modification channel FCCH, a synchronization channel SCH, a paging channel PCH, an access grant channel AGCH, a standalone dedicated control channel SDCCH, and a low speed related control channel SACCH. The physical control channel uplinks are a random access channel RACH, a standalone dedicated control channel SDCCH and a low speed related control channel SACCH. Further information on this structure and the purpose of these channels can be found in the GSM specification and document "An introduction to GSM", S.M. M. Redori, M. K. Webber, M .; W. Olyphant, Artechaus, London, 1995, ISBN 0-89006-785-6. Base station 100 maintains a list of physical channels allowed for it. During commissioning of the network, base station 100 is provided with a list of physical channels that base station 100 can use for traffic. Thereafter, when the network is ready for use, the network operator may change the list of allowed channels by the network management system, if desired, or some network element, eg, base station controller 114, The list of frequencies allowed for the base stations 100, 102 it manages is automatically reorganized so that the range of frequencies allowed for the network or parts of the network managed by the base station controller 114 is maintained. I do. The list of allowed physical channels may include the entire frequency range assigned to the operator, or may include only a portion thereof. In the first case, the entire network operates dynamically, so each base station allocates all physical channels available to the operator, the best of which is used for each particular situation. Is selected. According to another aspect, each base station optionally has a small portion of the operator's full frequency range. Thus, the use of frequency is generally planned at an approximate level. The base station 100 and / or the subscriber terminal 104 checks the list of allowed channels and measures the interference level of each physical channel. This measurement is repeated randomly or periodically. The measurement device maintains a list of its channels. The list is implemented in a number of different ways, for example, where the channels are divided into different classes, for example, into busy channels, non-interfering channels and potentially interfering channels. Another way to implement the list is to arrange the physical channels such that the first channel in the list contains little or no interference and the last channel in the list contains the most interference or is in use It is. The other channels in the list are halfway between these two extremes and are arranged so that the level of interference rises. Base station 100 and / or subscriber terminal 104 select a physical channel to be used as a wireless link based on the measured interference level. The base station 100 selects the channel with the lowest interference level as the fixed physical control channel 200, 204 from the allowed physical channels measured by the base station 100. The base station 100 then transmits the logical control channel on the at least one low-interference physical channel 200 that it has selected. Thus, the base station 100 uses a low-interference physical channel, for example, when transmitting control channels important for establishing a connection. Thereby, the quality of service received by the user is improved. This is because the subscriber terminal 104 can reliably establish a connection 108 to the base station 100. Correspondingly, the subscriber terminal 104 uses the low interference physical control channel 204 selected by the base station 100. The fixed physical control channel is usually selected during commissioning of the base station or when the network topology changes. The base station 100 probably informs the base station controller 114 of the physical channel it has selected. Next, the base station controller 114 notifies the adjacent base station 102 of the base station 100 which physical channel the base station 100 uses. The base station 100 detects a training sequence contained in a transmission unit or burst to be used to transmit the physical channel and, for that use, identifies at least one training sequence that is not used by a neighboring base station 102. Select and notify base station controller 114 of it. The training sequence is a bit sequence known to both the base station 100 and the subscriber terminal 104 that helps the receiver synchronize with the received burst. In establishing a two-way radio link, portions of the signal transmission normally performed on separate physical control channels 200, 204 can be moved to perform on already selected physical traffic channels 202, 206. . Thus, the capacity of the SDCCH channel is saved, and a handover is performed directly from the RACH channel to the selected traffic channel 202, 206 when establishing the wireless link 108. Accordingly, the signaling required to establish link 108 occurs on traffic channels 202,206. No physical SDCCH channel is needed, and the FACCH channel associated with the link traffic channels 202, 2062 is used for signal transmission. The coverage of the traffic channels 202, 206 can be estimated to be better than the control channels 200, 204. This is because the link has only two parties in the traffic channel, while many different subscriber terminals 104, 106 use the same control channel. The subscriber terminal 104 selects the channel with the lowest interference level as the physical channel downlink 202 from the allowed physical channels it has measured. Accordingly, the subscriber terminal 104 measures the interference level of the physical channel at the allowed frequency. In the system information, the subscriber terminal 104 receives from the base station 100 information on which of the allowed channels the subscriber terminal can select its traffic channel. The subscriber terminal 104 maintains a list of its channels. This list is, for example, similar to the above list and is maintained by the base station 100. In selecting the physical traffic channel uplink 206, there are two options. The downlink 202 of the physical traffic channel and the uplink 206 of the physical traffic channel to be used as the wireless link 108 can be individually selected if the frequency spacing between them is of random size. . This means, for example, that a fixed duplex spacing of 45 MHz used for the GSM standard is not always valid and that both downlink and uplink traffic channels are selected such that the interference is as low as possible. Accordingly, the subscriber terminal 104 or the base station 100 selects the channel with the lowest interference level from the allowed physical channels measured by the base station 100. If a fixed duplex interval is used, the physical channel located at a fixed frequency interval distance from the downlink of the selected physical channel is selected as the physical channel uplink. The selection of the traffic channels 202, 206 is a problem not only in establishing the link 108 but also in handover. Handover is, for example, an intra-cell handover due to a severe degradation of the channel quality due to increased interference, ie a handover from a physical channel to another channel in the cell. Also, an inter-cell handover is conceivable, which means that the link 108 is handed over from one base station 100 to another base station 102. The subscriber terminal uses the system information distributed by base station 100 while selecting traffic channels 202,206. The system information distributed by the base station 100 means information distributed by the base station 100 to a certain logical control channel by broadcast type transmission. This system information can change in the manner of implementation. This system information includes a list of allowed channels. In this regard, the list of allowed channels is intended for use by the subscriber terminal 104, 106 to select its traffic channel 202, 206 as described above. The system information may include the type of each adjacent base station 102. Notifying the subscriber terminal 104 of the type of neighbor base station 102, eg, GSM phase 1, GSM / DCS phase 2, DS (dynamic selection), helps the subscriber terminal 104 plan its operation. While performing the possible handover to the neighboring base station 102, the subscriber terminal 104 knows if the procedure described in the present invention is used there. This makes it possible to build a network comprising both a base station according to the prior art and a base station according to the invention together. The system information may include a list of channels allowed for each neighboring base station 102. In this channel, the subscriber terminal 104 performs measurements of the radio fields it has received, and possibly interference measurements in preparation for possible handover. The system information may include identification data of a physical channel including a BCCH channel of each adjacent base station, for example, a frequency and a time slot in the case of a synchronous wireless network. Here, the subscriber terminal 104 does not need to measure all the channels allocated by the adjacent base station 102, and the subscriber terminal 104 measures only the radio field received on the physical channel including the BCCH channel. The system information may include information regarding an uplink interference level of a physical traffic channel. Thus, the subscriber terminal 104 finds out how the coverage of the channel is going to the base station 100, and the subscriber terminal 104 uses this information when selecting its traffic channel as described above. . The system information may include a list of assigned physical channels. Thus, the subscriber terminal is informed which channel has already been assigned. Interference measurements on these channels are no longer needed and subscriber terminal 104 indicates them as assigned. The system information may include a quality threshold for channel selection. The quality threshold for channel selection means the lower limit of the interference level, below which the channel is in the right state and above which the channel contains too much interference for reliable traffic. The system information may include a quality threshold for intra-cell handover. This threshold, above which, means the interference level limit of the radio link that requires the base station 100 to move the subscriber terminal 104 to another channel of good coverage. The system information may also include limits for inter-cell handover. When the subscriber terminal 104 is active and uses discontinuous transmission, the subscriber terminal 104 performs measurements of neighboring base stations 102 during its transmission interruption to find possible inter-cell handover needs. be able to. In frequency hopping, the subscriber terminal 104 selects a physical channel to be used for the frequency hopping sequence. Thus, the method of the present invention also works in GSM / DCS based cellular wireless networks using frequency hopping. When the subscriber terminal 104 selects a traffic channel, it requests the base station to accept the physical traffic channel it proposes. At this time, the subscriber terminal 104 signals identification data of at least one physical channel selected by the subscriber terminal 104 to the base station 100 via the RACH channel, that is, at least one selected low-interference level signal that the subscriber terminal 104 wishes to use as a traffic channel. Signal which physical channel is. This is done during connection establishment, ie when engaging in both mobile outgoing and mobile incoming calls. This can also be done during a call, so that the signaling associated with the handover is performed on the FACCH channel associated with the old traffic channel. The base station 100 informs via the AGCH channel whether to accept at least one traffic channel proposed by the subscriber terminal 104. As described above, the subscriber terminal 104 starts traffic on the proposed at least one traffic channel immediately after the subscriber terminal 104 receives the acceptance signal of the proposed at least one traffic channel from the base station. So that you can move. The signaling associated with establishing the connection then takes place on the traffic channel. It is also conceivable that the signaling associated with the establishment of the connection is carried out in the usual way as defined in the GSM standard, before the use of the proposed traffic channel is not started. When the base station 100 rejects the traffic channel proposed by the subscriber terminal 104, the subscriber terminal 104 proposes at least one other traffic channel. The base station 100 can reject the traffic channel proposed by the subscriber terminal 104 if the quality of the channel is not good enough for traffic from the base station's point of view. The base station 100 can reject the traffic channel proposed by the subscriber terminal 104 only a predetermined number of times. However, the base station has more processing capacity for signal and good antenna post-processing, so that channel selection for the subscriber terminal 104 is optimized in adverse situations. Channel selection can also be considered unsuccessful, in which case it must be performed again. FIG. 3 showing the structures of the base station 100 and the base station controller 114 in detail will be described. The base station controller 114 is connected to the base station 100. Base station controller 114 is connected to mobile telephone switch 116. Base station controller 114, base station 100, and mobile telephone switch 116 are typically separate devices. Further, systems are known in which the operations of the base station 100 and the base station controller 114 are combined into a single device. The operation of mobile telephone switch 116 can also be combined into that single device. The role of the mobile telephone switch 116 is, for example, to realize a switching network, control connection establishment and release, collect billing data, and control an echo canceling device. Base station controller 114 monitors and controls multiple base stations 100. Typically, there is one base station controller 114 for tens or hundreds of base stations 100. The base station controller 114 includes a group switching network 302, a transcoder 304, and a control unit 306. Group switching network 302 is used to switch speech and data and to connect signal circuits. The transcoder 304 converts the different digital speech code modes to be used between the public telephone network and the mobile telephone network so that they can be compatible with each other. The control unit 306 performs call control, mobility management, statistical data and signal collection. Base station 100 typically comprises one to sixteen transceivers, each representing eight physical channels in GSM. The base station 100 includes a frame unit 312, a frequency hopping unit 314, a carrier unit 316, an antenna 318, and a control and maintenance unit 324. In the downlink, channel coding, channel interleaving, data encryption, and burst formation are performed in the frame unit 312. In the uplink, digital demodulation, data decryption, channel interleaving, and channel decoding are performed in the frame unit 312. In the frequency hopping unit 314, the frequency hopping of the fundamental band wave is performed. The carrier unit 316 includes a transceiver 320 and a receiver 322. Modulation (eg, GMSK modulation) and power amplification of the signal to be transmitted is performed at transmitter 320 of carrier unit 316. A / D conversion of the received signal and RSSI measurement are performed by the receiver 322 of the carrier unit 316. The control and maintenance unit 324 controls and monitors the operation of other units of the base station 310. Base station 100 generally includes a number of frame units 312 and corresponding carrier units 316. Base station 100 is configured to maintain a list of allowed physical channels. Further, base station 100 is configured to measure the interference level of the allowed physical channel. Base station 100 is also configured to select a physical channel to be used for the wireless link based on the measured interference level. The simplest way of implementing the invention is to convert the steps of the method of the invention to run as software. Thus, the software can be located, for example, in the processor memory included in the control and maintenance portion 324 of the base station 100. At this time, the control part 324 controls the receiver 320 to measure the interference level of the channel, and controls the frame unit 312 and the transmitter 322 so that the logical control channel is transmitted on a certain physical channel. I do. On the other hand, the present invention can be implemented in an ASIC circuit, or can be implemented in a separate logic configured by a separate HW part. Reference is now made to FIG. 4 which briefly illustrates a possible structure of the subscriber terminal 104. The subscriber terminal 104 includes a user part 400, a radio part 420, a control unit 450, and an antenna 470. The role of the user part 400 is to act as the user interface of the subscriber terminal 104. The role of the radio section 420 is to convert the signal to be transmitted to conform to the wireless link 108 and to convert the received signal to a user's understanding. The role of antenna 470 is to receive signals from and transmit signals to wireless link. The user part 400 includes a speaker 402, a display 404, a keyboard 406, and a microphone 408. The radio section 420 includes a receiver 430, a transmitter 440, a control unit 450, and a duplex filter 460. The receiver 430 includes a demodulator 432, a decryptor 434, a channel decoder 436, and a source decoder 438. The transmitter includes a source coder 442, an encryptor 444, a channel coder 446, and a modulator 448. The signal is received at antenna 470 and from there is sent through duplex filter 460 to receiver 430. First, the signal is demodulated in demodulator 432. The cipher is then decrypted at the decryptor 434. Thereafter, the signal is decoded in the channel decoder 436. Finally, the received information is converted to a form that can be displayed by the source decoder 438, then the speech information is sent to the speaker 402, and the signal sent from the base station 100 is processed in the control unit 450. . When information to be transmitted arrives from the microphone 408 and the control unit 450 to the transmitter 440, the speech information is digitized, and subsequently a codeword is formed from the digitized speech information and the signal at the source coder 442. . The information to be transmitted is then encoded in channel coder 444, and then encrypted in encryptor 446. The information is then modulated by modulator 448. Finally, the information to be transmitted is sent to antenna 470 via duplex filter 460. What is important for the present invention is that the control unit 450 controls the units connected to it in the figure. The subscriber terminal 104 of the cellular radio network according to the invention involves modifying the usual structure as follows. That is, the subscriber terminal 104 is configured to measure the interference level of the allowed physical channel. This measurement is performed according to known techniques so that control unit 450 controls receiver 430 to change its frequency and measure the interference level of each allowed channel. Further, the subscriber terminal 104 is configured to select a physical channel to be used as a wireless link based on the measured interference level. In the simplest implementation of the invention, the software required for control unit 450, in addition to normal operation, can decode the modulated signal received from base station 410 and transmit the signal. And the interference level can be measured as described above. In addition, the above operation can be performed by, for example, an ASIC circuit, or can be performed by a separate logic configured by the HW part. As described above, the present invention has been described with reference to the accompanying drawings. However, the present invention is not limited to this, and it is apparent that various modifications can be made within the scope of the present invention described in the claims. There will be.

[Procedure amendment] [Date of submission] October 25, 1999 (1999.10.25) [Content of amendment] Claims 1. A method for selecting a physical channel in a GSM / DCS based cellular wireless network, wherein said cellular wireless network is connected to said base station (100) by at least one base station (100) and a two-way wireless link (108). At least one fixed physical control channel downlink and at least one fixed physical control channel uplink, the bidirectional radio link (108) comprising at least one fixed physical control channel downlink and at least one fixed physical control channel uplink. A base station (100) configured by one physical traffic channel downlink and at least one physical traffic channel uplink, wherein a logical channel is arranged on the physical channel; Against Including a list of assigned physical channels, measuring the interference level of the allowed physical channel, and selecting a physical channel to be used as the radio link (108) based on the measured interference level Selecting a physical channel located at a fixed frequency spacing distance from a downlink of the selected physical traffic channel as an uplink of the physical traffic channel. 2. A method for selecting a physical channel in a GSM / DCS based cellular wireless network, wherein said cellular wireless network is connected to said base station (100) by at least one base station (100) and a two-way wireless link (108). At least one fixed physical control channel downlink and at least one fixed physical control channel uplink, the bidirectional radio link (108) comprising at least one fixed physical control channel downlink and at least one fixed physical control channel uplink. A base station (100) configured by one physical traffic channel downlink and at least one physical traffic channel uplink, wherein a logical channel is arranged on the physical channel; Against A list of physical channels allocated, measure the interference level of the allowed physical channel, and select a physical channel to be used as the radio link (108) based on the measured interference level. And the system information distributed by the base station (100) in such a way that the frequency spacing between the downlink of the physical traffic channel used for the radio link and the uplink of the physical traffic channel is of random size Is used for the selection, and the system information includes information on an uplink interference level of the physical channel. 3. The method of claim 2, wherein the system information includes a list of allowed channels. 4. The method according to claim 2, wherein the system information includes a quality threshold for channel selection. 5. The method of claim 2, wherein the system information includes a quality threshold for intra-cell handover. 6. The method of claim 2, wherein the system information includes a quality threshold for inter-cell handover. 7. A method for selecting a physical channel in a GSM / DCS based cellular wireless network, wherein said cellular wireless network is connected to said base station (100) by at least one base station (100) and a two-way wireless link (108). At least one fixed physical control channel downlink and at least one fixed physical control channel uplink, the bidirectional radio link (108) comprising at least one fixed physical control channel downlink and at least one fixed physical control channel uplink. A base station (100) configured by one physical traffic channel downlink and at least one physical traffic channel uplink, wherein a logical channel is arranged on the physical channel; Against A list of physical channels allocated, measure the interference level of the allowed physical channel, and select a physical channel to be used as the radio link (108) based on the measured interference level. And wherein the frequency spacing between the downlink of the physical traffic channel used as a radio link and the uplink of the physical traffic channel is of random size, the subscriber terminal (104) A method comprising requesting a base station (100) to accept a proposed physical traffic channel. 8. The subscriber terminal (104) transmits identification data of the at least one physical channel selected by the subscriber terminal (104) via the RACH channel to the base station (100). 8. The method according to claim 7, wherein the method informs via the AGCH channel whether to accept at least one traffic channel proposed by the group. 9. The method according to claim 8, wherein when the base station (100) rejects a traffic channel proposed by the subscriber terminal (104), the subscriber terminal (104) proposes at least one other traffic channel. 10. The method according to claim 9, wherein the base station (100) rejects the traffic channel proposed by the subscriber terminal (104) a predetermined number of times. 11. A system for selecting a physical channel in a GSM / DCS based cellular radio system, wherein the cellular radio network is connected to the base station (100) by at least one base station (100) and a two-way radio link (108). At least one fixed physical control channel downlink, at least one fixed physical control channel uplink, and at least one fixed physical control channel uplink. One physical traffic channel downlink and at least one physical traffic channel uplink, wherein a logical channel is arranged on the physical channel, and the base station (100) is connected to the base station (100). Allowed The base station (100) and / or the subscriber terminal (104) are configured to maintain a list of physical channels, and configured to measure an interference level of its allowed physical channel, and In a system, wherein the station (100) is configured to select a physical channel to be used as a radio link (108) based on its measured interference level, wherein the base station (100) is selected A system configured to select a physical channel located a fixed frequency interval from a downlink of a physical traffic channel as an uplink of the physical traffic channel.

────────────────────────────────────────────────── ─── Continuation of front page    (81) Designated country EP (AT, BE, CH, CY, DE, DK, ES, FI, FR, GB, GR, IE, I T, LU, MC, NL, PT, SE), OA (BF, BJ , CF, CG, CI, CM, GA, GN, ML, MR, NE, SN, TD, TG), AP (GH, GM, KE, L S, MW, SD, SZ, UG, ZW), EA (AM, AZ , BY, KG, KZ, MD, RU, TJ, TM), AL , AM, AT, AU, AZ, BA, BB, BG, BR, BY, CA, CH, CN, CU, CZ, DE, DK, E E, ES, FI, GB, GE, GH, GM, GW, HU , ID, IL, IS, JP, KE, KG, KP, KR, KZ, LC, LK, LR, LS, LT, LU, LV, M D, MG, MK, MN, MW, MX, NO, NZ, PL , PT, RO, RU, SD, SE, SG, SI, SK, SL, TJ, TM, TR, TT, UA, UG, US, U Z, VN, YU, ZW [Continuation of summary] Random frequency spacing between link and uplink Size.

Claims (1)

[Claims]   1. Physical Channels in GSM / DCS-Based Cellular Wireless Networks A method of selecting a cell, wherein the cellular wireless network comprises at least one Base station (100) and two-way radio link (108) At least one subscriber terminal (104) connected to the The two-way radio link (108) has at least one fixed physical control channel down. Uplink and at least one fixed physical control channel uplink; At least one physical traffic channel downlink and at least one The physical traffic channel uplink and the physical traffic channel A logical channel is arranged on the channel, and the base station (100) , List the allowed physical channels for that base station (100) Measure the interference level of its allowed physical channel, and The physical channel to be used as (108) is based on its measured interference level. In the method of selecting based on   The base station (100) receives the measured physical The channel with the lowest interference level as the fixed physical control channel. And selecting.   2. The fixed physical control channel communicates the base station (100). Selected when partitioning or when the topology of the network changes The method of claim 1.   3. The list of allowed physical channels is assigned to the operator The method of claim 1 including the entire frequency range.   4. The list of allowed physical channels is assigned to the operator The method of claim 1, comprising a portion of a frequency range.   5. The base station (100) detects a training sequence and And at least one tray not used by its adjacent base station (102). The base station controller (1 The method according to claim 1, wherein the notification is sent to 14).   6. Physical Channels in GSM / DCS-Based Cellular Wireless Networks A method of selecting a cell, wherein the cellular wireless network comprises at least one Base station (100) and two-way radio link (108) At least one subscriber terminal (104) connected to the The two-way radio link (108) has at least one fixed physical control channel down. Uplink and at least one fixed physical control channel uplink; At least one physical traffic channel downlink and at least one The physical traffic channel uplink and the physical traffic channel A logical channel is arranged on the channel, and the base station (100) , List the allowed physical channels for that base station (100) Measure the interference level of its allowed physical channel, and The physical channel to be used as (108) is based on its measured interference level. In the method of selecting based on   Fixed frequency spacing from downlink for selected physical traffic channel Physical channels located at a distance of A method characterized by selecting as a link.   7. Physical Channels in GSM / DCS-Based Cellular Wireless Networks A method of selecting a cell, wherein the cellular wireless network comprises at least one Base station (100) and two-way radio link (108) At least one subscriber terminal (104) connected to the The two-way radio link (108) has at least one fixed physical control channel down. Uplink and at least one fixed physical control channel uplink; At least one physical traffic channel downlink and at least one The physical traffic channel uplink and the physical traffic channel A logical channel is arranged on the channel, and the base station (100) , List the allowed physical channels for that base station (100) Measure the interference level of its allowed physical channel, and The physical channel to be used as (108) is based on its measured interference level. In the method of selecting based on   The downlink of the physical traffic channel used as the radio link and The frequency spacing between the physical traffic channel and the uplink is random. A method characterized by being a size.   8. The selection of the physical traffic channel is made during call establishment A method according to claim 6.   9. The choice of the physical traffic channel is made during an intra-cell handover. The method according to claim 6 or 7, wherein the method is performed.   10. The choice of the physical traffic channel is made during inter-cell handover. The method according to claim 6 or 7, which is performed.   11. System information distributed by the base station (100) is used for selection The method according to claim 6 or 7, wherein the method is performed.   12. The system information of claim 11, wherein the system information includes a list of allowed channels. the method of.   13. The system information includes a format of each adjacent base station (102). 12. The method according to 11.   14． The system information includes the information on the allowed channels for each adjacent base station (102). The method of claim 11, comprising a list of channels.   15. System information relates to the interference level of the physical channel uplink The method of claim 11, comprising information.   16. The system information includes a list of allowed physical channels. The method described in.   17． System information is a quality threshold for channel selection 12. The method of claim 11, comprising a code.   18. System information includes quality thresholds for intra-cell handover The method of claim 11, including a hold.   19. System information is a quality threshold for inter-cell handover. The method of claim 11, including a hold.   20. The subscriber terminal (104) is active and uses discontinuous transmission When the subscriber terminal (104) needs to perform a possible inter-cell handover, Measurement of adjacent base station (102) during its transmission interruption to find out The method according to claim 6, wherein the method is performed.   21. When frequency hopping is used, the subscriber terminal (104) Request to select a physical channel to be used for frequency hopping sequence Item 8. The method according to item 6 or 7.   22. The subscriber terminal (104) is responsible for the physical traffic channel it proposes. The method according to claim 6 or 7, wherein the request for acceptance of the channel is made to the base station (100). Method.   23. The subscriber terminal (104) has at least one physical channel that it has selected. The channel identification data is transferred to the base station (100) via the RACH channel. And the base station (100) is provided by the subscriber terminal (104). AGC whether to accept at least one proposed traffic channel The method according to claim 22, wherein the notification is performed via the H channel.   24. The base station (100) is the one proposed by the subscriber terminal (104). When rejecting a traffic channel, the subscriber terminal (104) 24. The method according to claim 23, wherein at least one traffic channel is proposed.   25. Base station (100) proposed by subscriber terminal (104) The method of claim 24, wherein the traffic channel is rejected a predetermined number of times.   26. Physical channel in GSM / DCS based cellular radio system System that implements cell selection, this cellular radio network Base with at least one base station (100) and two-way radio link (108) At least one subscriber terminal (104) connected to the station (100). For example, the two-way radio link (108) has at least one fixed physical control channel. A downlink and at least one fixed physical control channel uplink; , At least one physical traffic channel downlink and at least one One physical traffic channel uplink comprising: The logical channel is placed on the physical channel, and the base station (100) , List the allowed physical channels for that base station (100) The base station (100) and / or the subscriber station. Terminal (104) may measure the interference level of the allowed physical channel. To And the base station (100) is used as a wireless link (108). To select the physical channel to be based on its measured interference level In the configured system,   The base station (100) receives the measured physical The channel with the lowest interference level as the fixed physical control channel. A system configured to select the information.   27. Physical channel in GSM / DCS based cellular radio system A cellular wireless network, at least One base station (100) and two-way radio link (108) At least one subscriber terminal (104) connected to the The directional radio link (108) has at least one fixed physical control channel down. A link and at least one fixed physical control channel uplink; At least one physical traffic channel downlink and at least one Physical traffic channel uplink and the physical traffic channel uplink. A logical channel is arranged on the channel, and the base station (100) Maintain a list of allowed physical channels for the base station (100) And the base station (100) and / or the subscriber terminal (104) is configured to measure the interference level of its allowed physical channel. And the base station (100) should be used as a wireless link (108). Configured to select a physical channel based on its measured interference level In the implemented system,   The base station (100) is located on the selected physical traffic channel. Physical channels located at a fixed frequency distance from the downlink Note that it has been configured to be selected as an uplink for a traffic channel. Signing system.   28. Physical channel in GSM / DCS based cellular radio system A cellular wireless network, at least One base station (100) and two-way radio link (108) At least one subscriber terminal (104) connected to the The directional radio link (108) has at least one fixed physical control channel down. A link and at least one fixed physical control channel uplink; At least one physical traffic channel downlink and at least one Physical traffic channel uplink and the physical traffic channel uplink. A logical channel is arranged on the channel, and the base station (100) Maintain a list of allowed physical channels for the base station (100) And the base station (100) and / or the subscriber terminal (104) is configured to measure the interference level of its allowed physical channel. And the base station (100) should be used as a wireless link (108). Configured to select a physical channel based on its measured interference level In the implemented system,   Downlink of physical traffic channels used as radio links (108) Frequency spacing between the uplink and the physical traffic channel uplink A system characterized by its dumb size.