NO973093L - Radio system for cordless subscriber line interface - Google Patents

Description

The invention relates to a wireless, local loop system comprising base stations and a network access node which connects the wireless terminal equipment with the fixed network exchange. The system in particular comprises an air interface between the cordless terminal equipment and the base station, which interface is mainly in accordance with a TDMA mobile system where at least one time slot in a frame with signaling frequency (cO) is a control channel time slot where a base station transmits, with standard power, control information intended for cordless terminal equipment.

When a telephone network is built, not only is the installation of the subscriber lines between the exchange and the subscriber equipment considerably costly, but this installation also takes a lot of time. Usually, the network of subscriber lines is formed in such a way that park cables that start in several subscriber equipment are supplied to a distributor rack, and cables coming from several coordinate selectors are combined in another distributor rack, and the distributor rack's cable goes to the switchboard. The signaling interface between the exchange and the subscriber lines is standardized, and it is either an interface with analogue two-wire subscriber lines, a multiplexer interface according to recommendation V2 for CCITT, or a message-based multiplexer interface in accordance with recommendation V5.1 for ETSI. Changing fixed subscriber lines is difficult to carry out, and maintenance costs, especially in areas where the subscriber lines are overhead lines, can be considerable. One solution to these problems is to replace the fixed lines between the exchange and the subscriber equipment with radio lines. This solution is known as a wireless local loop system (WLL system, wireless local loop system).

The principle of the WLL system is shown in fig. 1. A wireless, stationary terminal equipment T comprises a radio unit 4 provided with an antenna, and a telephone adapter which connects a standard subscriber equipment 5 to the terminal equipment. The subscriber equipment can be a normal telephone unit, a fax terminal, or a modem. It is attached to the terminal equipment by inserting a standard plug into the terminal equipment's adapter connection. The user uses the subscriber equipment 5 in the same way as in a normal fixed network, even if the subscriber line connection consists of a radio line between the terminal equipment T and the base station BS2 or 3. The base station can operate several subscriber equipment. The base station is connected to a special network access node 1, which in turn is connected to a standard exchange. Several base stations can be connected to a network access node 1.

The WLL system can be built by using components in an existing mobile phone system. The mobile system can e.g. be an analogue NMT system, or a digital GSM system. In such a case, the signaling in the WLL system is consistent with the system in question, the base stations are standard base stations in this system, and the radio unit in the terminal equipment is similar to the radio unit of the mobile station, or the terminal equipment may be a mobile station in a mobile system. An important component of the WLL system is the network access node that connects the subscribers to the local standard exchange. The network access node transforms the WLL network signaling, e.g. NMT or GSM signalling, to signaling suitable for the fixed network (e.g. PSTN, public switched telephone network), and correspondingly, the node adapts the signaling in the fixed network to the WLL network's interface.

The network node is connected to the local exchange with an open V2- or V5.1-type multiplexer interface that uses a PCM system with 2 Mbit/s. If the local exchange only supports the two-wire interface, the network node is connected to the exchange by converting the V2 signaling to an analog subscriber loop interface with two wires by means of a multiplexer. The signaling between the network node and the base stations connected to it is the signaling in an adapted mobile network, but is modified in such a way that typical functions for a cellular network, such as handover between cells and "roaming", are prevented. Therefore, the subscriber must stay within the coverage area of the assigned base station. The routing of an incoming call and an outgoing call is based on the network node's subscriber database. The operation of the network node corresponds to the operation of a concentrator: a call is forwarded from a subscriber interface to the exchange, and the analysis of the numbers, calculation and other functions are carried out in the exchange.

In accordance with what is described above, a WLL network can be based on a known GSM system. GSM is a digital, cell-shared system based on time-shared multiple access. The system's channels shall be described below.

Logical channels are divided into traffic channels TCH, which transmit voice and data, and into control channels, which transmit signaling and synchronization data. Control channels include broadcast channels, common control channels and dedicated channels. Broadcast channels BCH are channels directed from a base station to a mobile station (in the downlink direction) and they include (i) a frequency correction channel FCCH with information used by the mobile station for frequency correction, (ii) a synchronization channel SCH which transmits frame synchronization information and the identification of the base station to the mobile station, and (iii) a broadcast control channel BCCH which transmits general information regarding the base station. Common control channels CCCH include in the downstream direction a paging channel PCH which is used to send paging messages to the mobile stations, in the upstream direction an arbitrary access channel RACH which is used by the mobile stations to request a channel from the network, and in the downstream direction an access message channel AGCH by means of which the network acknowledges the requests sent by the mobile stations. Dedicated channels include a stand-alone dedicated control channel SDCCH, and a slow associated control channel SACCH and a fast associated control channel FCCH associated with traffic channels.

Logical channels are mapped onto the radio path's physical channels. As is known, a physical channel consists of successive windows which are determined by means of a time slot and a frequency. A particular physical channel always uses the same time slot number in each TDMA frame which consists of eight time slots, but the frequency can change when frequency hopping is used.

51 TDMA frames form a control channel multiframe which is shown schematically in fig. 2. Both FCCH and SCH have the same structure: an SCH time slot follows an FCCH time slot at a distance of one frame, and the multiframe has five time slots reserved for each channel. Each channel uses the frame's time slot TNO. BCCH uses four time slots in the multiframe, and the time slots are in successive frames. The rest of the 36 time slots (each in its own TDMA frame) are reserved for the CCCH, i.e. in the case of a frame in the downlink direction, for PCH and AGCH, and in the case of a frame in the uplink direction, for the RACH. For practical reasons, both BCCH and CCCH also use timeslot TNO. The repetition length for the control channel multiframe is thus 51 durations of a TDMA frame. Frequency hopping is not permitted in time slot TNO, but the aforementioned channels that use this time slot must use the same fixed frequency. According to the specification, however, the BCCH carrier must be transmitted in all time slots constantly at a constant power and at a standard frequency, usually at the highest permitted power. The carrier wave frequency with which the control information is sent is denoted by cO. In the time slots where no information is sent, a so-called "blind data burst" (dummy burst) is formed by using "stuffing bits". The BCCH carrier wave cO, which is transmitted continuously with standard power and with a standard frequency, is used in such a way that a mobile station periodically measures the signal strength of the BCCH carrier wave in neighboring cells, and it also determines the connection quality by means of the bit error ratio, after which the measurement results are utilized in the handover procedure.

In the GSM system, error-correcting coding is used on the traffic channel to achieve as error-free radio transmission as possible. The coding is two-phase channel coding, where light block coding is used mainly for error detection, and convolutional coding is used for error correction. In convolutional coding, the errors must be arbitrarily distributed in time before the code can be used effectively. Therefore, interleaving is used, where a channel-coded block is sent in at least four time slots, the channel-coded block's bits being mixed before transmission so that transmission errors are made arbitrary, and adjacent blocks are interleaved to be sent in the same time slot. The interleaving as such is sufficient if the mobile station is moving, but frequency hopping is also used, since it improves the arbitrary enhancement of errors in the case of a slowly moving or stationary mobile station. Another advantage of frequency hopping is that the co-channel interference caused by another user in another cell using the same frequency is equalised. The reason for the coding and frequency hopping is that the received signal is a sum of Rayleigh fading signals with different delays, whereby the variation in signal level and quality is strong. The frequency hopping and hopping rate decrease, and at best eliminate the correlation between successive bursts, whereupon the errors are randomized through interleaving and bit reorganization.

However, a strong carrier wave that is transmitted continuously is a problem in some cases. It causes an increase in the network's interference level, i.e. when a traffic channel carrier in the cell is the same as the BCCH carrier of a neighboring cell, it causes interference in the reception. This reduces network capacity. In low-capacity cells where only one transmit and receive frequency, i.e. one TRX, is used on the traffic channel, there must be an additional transmitter/receiver in the base station if frequency hopping is used, and this additional transmitter/receiver transmits the BCCH carrier wave during the same time slot where the actual transmitter/receiver generates the traffic channel frequency. This is necessary since one transceiver can be used to synthesize a large number of frequencies, but only one frequency at a time.

These interference problems also concern the WLL system described in the introduction, when the GSM system as such is used for WLL use. Especially when the WLL system is used in sparsely populated areas, it is very likely that the base station only uses one transmission and reception frequency (a TRX frequency), and that the coverage area for the base station is large. In addition to the fact that the transmit power for the BCCH carrier is high, which increases the co-channel interference in the telephone traffic and reduces the capacity of the network, in such a case an additional transceiver must be placed in the base station for the purpose of frequency hopping to form The BCCH carrier cO. The frequency hopping is also necessary, or at least desirable, with a TRX, since the absence of frequency hopping causes a deterioration in the efficiency of the convolutional coding, because in the case of stationary or slow moving mobile stations, interleaving alone is not sufficient to produce a arbitrary error distribution. The network's capacity also decreases due to the fact that when the interference on the same channel is not equalized by means of frequency diversity, greater frequency diversity must be used, i.e. fewer channels are obtained with the same frequency allocation.

The object of the present invention is a wireless local loop system, based on the TDMA system and in particular the GSM system, in which system the BCCH carrier wave cO does not cause the type of problems described above, which would result from the use of a standard BCCH carrier wave in the GSM system.

The purpose is achieved in the manner stated in patent claim 1.

In the WLL radio system according to the invention, the BCCH carrier wave cO is sent with standard power only in the time slot where control information is sent, and in the other time slots the carrier wave is not sent at all, or the other time slots are used as needed for traffic channels in which BCCH the carrier's power is adjusted in the normal way. These other time slots thus contain no transmission if there is no traffic. If there is traffic, power management, frequency hopping and discontinuous transmission (DTX) are used. DTX means that the transmission is interrupted during breaks in the speech. Less interference, good frequency diversity and better code performance are thus achieved during reception.

In what follows, the invention will be described in more detail with reference to the attached drawings, where

fig. 1 shows the principle of the WLL system,

fig. 2 shows a multiframe in a control channel, and

fig. 3 is an example of the arrangement with the BCCH carrier according to the invention.

In WLL applications, a subscriber can move within his home cell, but handover between cells is prevented. Therefore, it is not necessary to measure the strength of the BCCH carrier in nearby stations. In the WLL system according to the invention, therefore, the BCCH carrier wave does not need to be transmitted continuously in all time slots in the frame that uses this carrier frequency cO, but it is transmitted with maximum power only in the time slots that form BCCH and CCCH. This time slot is time slot TNO in RF channel cO in fig. 3. The other time slots TN1TN7 in the frame that use the carrier frequency cO can be used as traffic channel time slots if necessary. In these time slots, power control is normally used for the frequency cO. Since the carrier wave is not transmitted at maximum power, or not transmitted at all, the co-channel interference decreases considerably.

When only one TRX, in fig. 3 frequency cO, is assigned to a cell, frequency hopping between the BCCH frequency cO and the frequency d to be synthesized can still be performed using the same transmitter/receiver. A possible channel that uses frequency hopping is described with arrows that combine the time slots in these RF channels. The channel is formed by the fourth time slot in the frame. One frequency synthesizer is sufficient, because when a burst is transmitted in the fourth time slot for frequency c1, it is not necessary at all to transmit a BCCH carrier wave in the simultaneous fourth time slot for frequency c0.

When several TRX frequencies are allocated to a cell, the frequency hopping can be performed between these frequencies and the BCCH carrier cO can be turned off in the time slots TN1,..., TN7. These timeslots can of course be used for traffic channels, whereby normal power control is carried out on the carrier waves, and these timeslots can also be used for frequency hopping.

When the arrangement according to the invention is used for the BCCH carrier, certain features of the standard GSM system can be omitted: handover algorithms are not necessary, and therefore the base station does not need to send any list of neighboring cells, and a subscriber equipment does not need to monitor the neighboring cells' BCCH carrier wave and perform measurements related to this, or report the measurement results to the network. If frequency hopping is not performed, the BCCH carrier does not need to be transmitted continuously, but only in time slot TNO.

A further advantage of the invention is that, particularly in the case of low-capacity cells, frequency reuse is more efficient in the network, since a strong carrier wave is not on all the time. Furthermore, the power consumption of the terminal equipment decreases, since there is no need to monitor the BCCH carrier for the neighboring base stations. This is important, since the terminal equipment is in most cases battery-powered.

It should be understood that the above description and the figures associated therewith are only intended to illustrate the present invention. Various variations of the invention will be obvious to those skilled in the art, without any deviation from the scope and idea of the invention set forth in the appended claims.

Claims (7)

1. Wireless local loop system comprising base stations and a network access node connecting the wireless terminal equipment (T) to the exchange in the fixed network, where the air interface between the cordless terminal equipment and the base station (2, 3) is mainly in accordance with a TDMA -mobile system where at least one time slot (e.g. TNO) in a frame with a carrier wave that is the basic carrier wave (cO) for signaling is a time slot in a control channel (FCCH, SCH, BCCH, CCCH), in which time slot the base station transmits, with constant power, control information intended for the cordless terminal devices, characterized by the fact that in the frame's other time slots (e.g. TN1, TN7) the burst of data is only sent in the required time slots (e.g. TN2). 2. Radio system according to claim 1, characterized in that the time slot (e.g. TN2) where the data burst is sent is a traffic channel time slot, and that the transmission power for the signaling carrier wave (cO) which acts as a carrier wave for the data burst is adjusted in a manner required by the mobile system. 3. Radio system according to claim 1, characterized in that when the frame time slot is different from a traffic channel time slot or a control channel time slot, the signaling carrier wave (cO) is not sent at all. 4. Radio system according to claim 1, characterized in that frequency hopping is permitted in the traffic channel time slot of the frame. 5. Radio system according to claim 2 or 4, characterized in that discontinuous transmission (DTX) is used on the traffic channel. 6. Radio system according to claim 1 or 4, characterized in that in the system a TRX frequency, which is the signaling carrier frequency (cO), and at least one other frequency (d) are allocated to the base station, and that on the traffic channel the frequency hopping takes place between the TRX frequency and another frequency (c1 ), whereby both frequencies are formed with the same frequency synthesizer. 7. Radio system according to claim 1, characterized in that the cordless terminal equipment (T) only listens to information sent on the control channel by the base station assigned to the terminal equipment.