WO1998031176A2 - Controlling interference in a cell of a wireless telecommunications system - Google Patents
Controlling interference in a cell of a wireless telecommunications system Download PDFInfo
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- WO1998031176A2 WO1998031176A2 PCT/US1997/022797 US9722797W WO9831176A2 WO 1998031176 A2 WO1998031176 A2 WO 1998031176A2 US 9722797 W US9722797 W US 9722797W WO 9831176 A2 WO9831176 A2 WO 9831176A2
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- channel
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- division multiplexed
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Classifications
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/50—Allocation or scheduling criteria for wireless resources
- H04W72/54—Allocation or scheduling criteria for wireless resources based on quality criteria
- H04W72/541—Allocation or scheduling criteria for wireless resources based on quality criteria using the level of interference
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/04—Wireless resource allocation
- H04W72/044—Wireless resource allocation based on the type of the allocated resource
- H04W72/0466—Wireless resource allocation based on the type of the allocated resource the resource being a scrambling code
Definitions
- the present invention relates in general to wireless telecommunications systems and more particularly to techniques for controlling interference in a cell of a wireless telecommunications system.
- a wireless telecommunications system has been proposed in which a geographical area is divided in to cells, each cell having one or more central terminals (CTs) for communicating over wireless links with a number of subscriber terminals (STs) in the cell.
- CTs central terminals
- STs subscriber terminals
- These wireless links are established over predetermined frequency channels, a frequency channel typically consisting of one frequency for uplink signals from a subscriber terminal to the central terminal, and another frequency for downlink signals from the central terminal to the subscriber terminal .
- 16 orthogonal channels can be created within a single frequency channel, and hence up to sixteen separate communication signals (corresponding to sixteen separate wireless links) can be transmitted simultaneously over the single frequency channel if different orthogonal codes are applied to each communication signal.
- This problem is alleviated somewhat by adopting a deployment arrangement whereby adjacent cells all use different frequency channels.
- an interference controller for limiting in one cell the effect of interference generated by other cells of a wireless telecommunications system, each cell of the wireless telecommunications system having a central terminal and a plurality of subscriber terminals, communication between a central terminal and a subscriber terminal being arranged to occur over a wireless link, a plurality of code division multiplexed channels being provided within a single frequency channel to enable data items pertaining to a plurality of wireless links to be transmitted simultaneously within different code division multiplexed channels of said single frequency channel, the interference controller comprising: an analyser for comparing with predetermined criteria parameters within the cell indicative of whether the code division multiplexed channels are subject to interference from signals generated by said other cells; and a channel controller, responsive to the analyser, to selectively prevent code division multiplexed channels from being used in order to reduce the effect of the interference from said other cells.
- the effects of interference from other cells can be suppressed, since taking a code division multiplexed channel out of commission enhances the interference rejection of the remaining code division multiplexed channels. Further, it is not just the effect of interference from other cells which is reduced, but also the effect of any internal interference within the cell, such as multipath interference, will also be reduced. Taking a code division multiplexed channel out of commission may affect the number of calls that can be handled simultaneously by the cell, but will enable the cell to retain a satisfactory quality where no calls are affected to an unacceptable degree by outside interference.
- a parameter provided to the analyser is the bit error rate (BER) for signals transmitted within said code division multiplexed channels, and the predetermined criteria with which the analyser compares said BER is a threshold BER value identifying a predetermined maximum acceptable BER, the channel controller being responsive to the analyser indicating that the BER exceeds the predetermined maximum acceptable BER to remove a code division multiplexed channel from use.
- BER bit error rate
- a BER signal can be provided to the analyzer for each uplink and downlink communication path, the BER signal giving an indication of the errors introduced by interference during the transmission of a data signal over the particular wireless link. Hence, for each wireless link, the analyser can be provided with information about the interference levels being experienced on those links.
- an additional parameter preferably provided to the analyser is a grade of service (GOS) signal indicative of the availability of the code division multiplexed channels, and the predetermined criteria with which the analyser compares said GOS signal is a threshold GOS value identifying a predetermined maximum grade of service, the channel controller being responsive to the analyser indicating that the GOS signal has exceeded the predetermined maximum grade of service to remove a code division multiplexed channel from use.
- GOS grade of service
- each subscriber terminal and each modem on a modem shelf within the central terminal will have a call control function associated therewith.
- the call control function within an ST will collect information about how readily the ST is able to acquire an uplink channel for incoming or outgoing calls, whilst each call control functions within the CT will monitor how readily the modems within the CT can establish downlink channels.
- the analyser will in preferred embodiments receive information indicative of how readily the modems within the CT and each ST is able to acquire channels. If the GOS exceeds that which would be considered acceptable (as indicated by the predetermined maximum GOS) , then the channel controller can remove a code division multiplexed channel from use with the aim of reducing the effect of interference within the remaining code division multiplexed channels.
- the channel controller upon receipt of a signal from the analyser indicating that a code division multiplexed channel should be removed from use, is arranged to determine which code division multiplexed channel is least heavily used, and to remove that code division multiplexed channel from use. This ensures that the least number of users are affected by the removal of the code division multiplexed channel.
- the channel controller might be arranged to remove the least heavily used channel that is not handling, or reserved for handling, a priority call.
- it may be acceptable for the channel controller not to react to the request from the analyser to remove a channel, until such time as a channel is completely free of traffic, and to then remove that channel from use.
- a plurality of the code division multiplexed channels are designated as traffic channels
- the analyser is arranged to monitor the parameters relating to interference on those traffic channels
- the channel controller is arranged to selectively designate one or more of said traffic channels as locked channels which should not be used in order to reduce the effect of the interference from said other cells .
- the channel controller is arranged to designate one of said locked channels as a free traffic channel which can subsequently be used for data traffic.
- the channel controller can add another code division multiplexed channel to the pool of traffic channels, thereby improving the GOS.
- the channel controller is arranged to designate one of said locked channels as a free traffic channel which can subsequently be used for data traffic.
- the channel controller is provided with a value indicating a maximum number of code division multiplexed channels that can be designated as traffic channels, the channel controller only adding code division multiplexed channels upon request from the analyser if doing so would not exceed the maximum number of code division multiplexed channels.
- a number of the traffic channels are reserved as call channels, and a number of the traffic channels are designated as free channels, and if a call channel is used to pass call data, the channel controller is arranged to designate a free channel as a call channel if a free channel is available, thereby improving the chance of a call channel being available for a subsequent call.
- said code division multiplexed channels are orthogonal channels, a set of orthogonal codes being used to create said orthogonal channels .
- an interference controller in accordance with the invention is provided within a central terminal for a cell of a wireless telecommunications system, the telecommunications system having a plurality of cells, and each cell having a central terminal and a plurality of subscriber terminals, communication between the central terminal and a subscriber terminal in said cell being arranged to occur over a wireless link, a plurality of code division multiplexed channels being provided within a single frequency channel to enable data items pertaining to a plurality of wireless links to be transmitted simultaneously within different code division multiplexed channels of said single frequency channel.
- the provision of the interference controller within the central terminal enables the CT to limit the effect of interference generated by other cells of said wireless telecommunications system.
- the central terminal would typically further comprise: an orthogonal code generator for providing an orthogonal code from a set of orthogonal codes used to create said code division multiplexed channels within the single frequency channel; a first encoder for combining a data item to be transmitted on the single frequency channel with said orthogonal code from the orthogonal code generator, the orthogonal code determining the code division multiplexed channel over which the data item is transmitted, thereby enabling data items pertaining to different wireless links to be transmitted simultaneously within different code division multiplexed channels of said single frequency channel.
- an orthogonal code generator for providing an orthogonal code from a set of orthogonal codes used to create said code division multiplexed channels within the single frequency channel
- a first encoder for combining a data item to be transmitted on the single frequency channel with said orthogonal code from the orthogonal code generator, the orthogonal code determining the code division multiplexed channel over which the data item is transmitted, thereby enabling data items pertaining to different wireless links to be transmitted simultaneously within different code division
- the present invention provides a wireless telecommunications system comprising a plurality of cells, each cell having a central terminal and a plurality of subscriber terminals, communication between a central terminal and a subscriber terminal within a cell being arranged to occur over a wireless link, a plurality of code division multiplexed channels being provided within a single frequency channel to enable data items pertaining to a plurality of wireless links to be transmitted simultaneously within different code division multiplexed channels of said single frequency channel, at least one cell of the wireless telecommunications system comprising an interference controller in accordance with the present invention for limiting the effect of interference generated by other cells of said wireless telecommunications system.
- the interference controller may further comprise a transmission controller for processing data items to be transmitted over a wireless link connecting a central terminal and a subscriber terminal of a wireless telecommunications system, a single frequency channel being employed for transmitting data items pertaining to a plurality of wireless links, the transmission controller comprising: an orthogonal code generator for providing an orthogonal code from a set of 'm' orthogonal codes used to create 'm' orthogonal channels within the single frequency channel; a first encoder for combining a data item to be transmitted on the single frequency channel with said orthogonal code from the orthogonal code generator, the orthogonal code determining the orthogonal channel over which the data item is transmitted, whereby data items pertaining to different wireless links may be transmitted simultaneously within different orthogonal channels of said single frequency channel; an overlay code generator for providing an overlay code from a first set of 'n' overlay codes which are orthogonal to each other; and a second encoder arranged to apply the overlay code from the overlay code generator to said data item, whereby
- the interference controller may further comprise a reception controller for processing data items received over a wireless link connecting a central terminal and a subscriber terminal of a wireless telecommunications system, a single frequency channel being employed for transmitting data items pertaining to a plurality of wireless links
- the receiver controller comprising: an orthogonal code generator for providing an orthogonal code from a set of 'ra' orthogonal codes used to create 'm' orthogonal channels within the single frequency channel; a first decoder for applying, to signals received on the single frequency channel, the orthogonal code provided by the orthogonal code generator, in order to isolate data items transmitted within the corresponding orthogonal channel; an overlay code generator for providing an overlay code from a first set of 'n' overlay codes which are orthogonal to each other, the set of 'n' overlay codes enabling ' n' data items pertaining to different wireless links to be transmitted simultaneously within the same orthogonal channel; and a second decoder for applying, to the data items of the orthogonal channel,
- orthogonal channels By using overlay codes in addition to a known set of orthogonal codes, it is possible for selected orthogonal channels to be subdivided to form additional orthogonal channels. For example, if there are originally sixteen orthogonal channels and a set of four overlay codes are defined, each orthogonal channel being subject to overlay codes, then up to 64 orthogonal channels can be defined. By application of appropriate orthogonal codes and overlay codes, up to 64 separate communication signals could be sent simultaneously on the one frequency channel, albeit at a quarter of the rate that the communication signals could be transmitted if the overlay codes were not used.
- Such an approach has the advantage that it preserves compatibility with current hardware and software equipment which use the set of orthogonal codes, but which do not support the use of overlay codes. By designating certain orthogonal channels as channels for which overlay codes are not used, the current equipment can communicate over those channels without any changes being required to the equipment .
- the interference controller may further comprise a transmission controller for processing data items to be transmitted over a wireless link connecting a central terminal and a subscriber terminal of a wireless telecommunications system, a single frequency channel being employed for transmitting data items pertaining to a plurality of wireless links, the transmission controller comprising: an orthogonal code generator for providing an orthogonal code from a set of • m' orthogonal codes used to create 'm' orthogonal channels within the single frequency channel; a first encoder for combining a data item to be transmitted on the single frequency channel with said orthogonal code from the orthogonal code generator, the orthogonal code determining the orthogonal channel over which the data item is transmitted, whereby data items pertaining to different wireless links may be transmitted simultaneously within different orthogonal channels of said single frequency channel; and a TDM encoder arranged to apply time division multiplexing (TDM) techniques to the data item in order to insert the data item within a time slot of the orthogonal channel, whereby a plurality of data items relating
- TDM
- the interference controller may further comprise a reception controller for processing data items received over a wireless link connecting a central terminal and a subscriber terminal of a wireless telecommunications system, a single frequency channel being employed for transmitting data items pertaining to a plurality of wireless links, and 'm' orthogonal channels being provided within the single frequency channel
- the receiver controller comprising: an orthogonal code generator for providing an orthogonal code from a set of ' m' orthogonal codes used to create said ' ' orthogonal channels within the single frequency channel; a first decoder for applying, to signals received on the single frequency channel, the orthogonal code provided by the orthogonal code generator, in order to isolate data items transmitted within the corresponding orthogonal channel; and a TDM decoder arranged to extract a data item from a predetermined time slot within said orthogonal channel, a plurality of data items relating to different wireless links being transmitted within the same orthogonal channel during a predetermined frame period.
- TDM techniques in addition to a known set of orthogonal codes, it is possible for selected orthogonal channels to be subdivided in the time dimension. For example, if TDM is used to divide one frame period in to four subframes, and each orthogonal channel is subject to the TDM technique, then up to 64 separate communication signals can be transmitted on the sixteen orthogonal channels during one frame period, albeit at a quarter of the rate that the communication signals could be transmitted if the TDM technique was not used.
- Such an approach has the advantage that it preserves compatibility with current hardware and software equipment which use the set of orthogonal codes, but which do not support the use of TDM techniques.
- the current equipment can communicate over those channels without any changes being required to the equipment.
- the interference controller may further comprise a channel selection controller for establishing a wireless link connecting a central terminal and a subscriber terminal of a wireless telecommunications system, at least two frequency channels being provided over which said wireless link could be established, the channel controller comprising: a storage for storing data identifying the at least two frequency channels; a selector for selecting a frequency channel from those listed in said storage; link acquisition logic for establishing a wireless link on the frequency channel selected by the selector; the selector being responsive to the link acquisition logic being unable to establish said wireless link, to select an alternative frequency channel from those listed in said storage.
- the present invention provides a method of limiting in one cell the effect of interference generated by other cells of a wireless telecommunications system, each cell of the wireless telecommunications system having a central terminal and a plurality of subscriber terminals, communication between a central terminal and a subscriber terminal being arranged to occur over a wireless link, a plurality of code division multiplexed channels being provided within a single frequency channel to enable data items pertaining to a plurality of wireless links to be transmitted simultaneously within different code division multiplexed channels of said single frequency channel, the method comprising the steps of: (a) employing an analyser to compare with predetermined criteria parameters within the cell indicative of whether the code division multiplexed channels are subject to interference from signals generated by said other cells; and (b) responsive to the analyser, selectively preventing code division multiplexed channels from being used in order to reduce the effect of the interference from said other cells.
- Figure 1 is a schematic overview of an example of a wireless telecommunications system in which an example of the present invention is included;
- Figure 2 is a schematic representation of a customer premises
- Figures 2A and 2B are schematic illustrations of an example of a subscriber terminal of the telecommunications system of Figure 1
- Figure 3 is a schematic illustration of an example of a central terminal of the telecommunications system of Figure 1 ;
- Figure 3A is a schematic illustration of a modem shelf of a central terminal of the telecommunications system of Figure 1 ;
- Figure 4 is an illustration of an example of a frequency plan for the telecommunications system of Figure 1;
- Figures 5A and 5B are schematic diagrams illustrating possible configurations for cells for the telecommunications system of Figure 1;
- Figure 6 is a schematic diagram illustrating aspects of a code division multiplex system for the telecommunications system of Figure 1;
- Figure 7 is a schematic diagram illustrating signal transmission processing stages for the telecommunications system of Figure 1 ;
- Figure 8 is a schematic diagram illustrating signal reception processing stages for the telecommunications system of Figure 1;
- Figure 9 is a schematic diagram illustrating downlink and uplink communication paths for the wireless telecommunications system
- Figure 10 is a schematic diagram illustrating the makeup of a downlink signal transmitted by the central terminal ;
- Figure 11 is a graphical depiction illustrating the phase adjustment to a slave code sequence of the subscriber terminal
- Figure 12 is a graphical depiction of a signal quality estimate performed by the receiver in the subscriber terminal ;
- Figure 13 is a graphical diagram illustrating the contents of a frame information signal within the downlink signal ;
- Figure 14 is a tabular depiction illustrating overhead insertion into a data stream of the downlink signal
- Figure 15 is a schematic block diagram of a frame alignment circuit of an embodiment of the invention.
- Figures 16A and 16B are timing diagrams for explaining the operation of the frame alignment circuit of Figure 15.
- Figure 16C is state diagram of a state machine of the frame alignment circuit of Figure 15;
- Figure 17 is a graphical depiction of a transmitting power and a transmit rate for each mode of operation of the wireless telecommunications system.
- Figure 18 is a schematic diagram illustrating the operation of the receiver and transmitter in the subscriber terminal .
- FIG. 1 is a schematic overview of an example of a wireless telecommunications system.
- the telecommunications system includes one or more service areas 12, 14 and 16, each of which is served by a respective central terminal (CT) 10 which establishes a radio link with subscriber terminals (ST) 20 within the area concerned.
- CT central terminal
- ST subscriber terminals
- the area which is covered by a central terminal 10 can vary. For example, in a rural area with a low density of subscribers, a service area 12 could cover an area with a radius of 15- 20Km.
- a service area 14 in an urban environment where is there is a high density of subscriber terminals 20 might only cover an area with a radius of the order of 100m.
- a service area 16 might cover an area with a radius of the order of lKm. It will be appreciated that the area covered by a particular central terminal 10 can be chosen to suit the local requirements of expected or actual subscriber density, local geographic considerations, etc, and is not limited to the examples illustrated in Figure 1. Moreover, the coverage need not be, and typically will not be circular in extent due to antenna design considerations, geographical factors, buildings and so on, which will affect the distribution of transmitted signals.
- the links can include conventional telecommunications technology using copper wires, optical fibres, satellites, microwaves, etc.
- the wireless telecommunications system of Figure 1 is based on providing fixed microwave links between subscriber terminals 20 at fixed locations within a service area
- Each subscriber terminal 20 can be provided with a permanent fixed access link to its central terminal
- demand-based access is provided, so that the number of subscribers which can be supported exceeds the number of available wireless links.
- the manner in which demand-based access is implemented will be discussed in detail later.
- Figure 2 includes a schematic representation of customer premises 22.
- Figures 2A and 2B illustrate an example of a configuration for a subscriber terminal 20 for the telecommunications system of Figure 1.
- a customer radio unit (CRU) 24 is mounted on the customer's premises.
- the customer radio unit 24 includes a flat panel antenna or the like 23.
- the customer radio unit is mounted at a location on the customer's premises, or on a mast, etc., and in an orientation such that the flat panel antenna 23 within the customer radio unit 24 faces in the direction 26 of the central terminal 10 for the service area in which the customer radio unit 24 is located.
- the customer radio unit 24 is connected via a drop line 28 to a power supply unit (PSU) 30 within the customer's premises.
- the power supply unit 30 is connected to the local power supply for providing power to the customer radio unit 24 and a network terminal unit (NTU) 32.
- the customer radio unit 24 is also connected via the power supply unit 30 to the network terminal unit 32, which in turn is connected to telecommunications equipment in the customer's premises, for example to one or more telephones 34, facsimile machines 36 and computers 38.
- the telecommunications equipment is represented as being within a single customer's premises. However, this need not be the case, as the subscriber terminal 20 preferably supports either a single or a dual line, so that two subscriber lines could be supported by a single subscriber terminal 20.
- the subscriber terminal 20 can also be arranged to support analogue and digital telecommunications, for example analogue communications at 16, 32 or 64kbits/sec or digital communications in accordance with the ISDN BRA standard.
- FIG 3 is a schematic illustration of an example of a central terminal of the telecommunications system of Figure 1.
- the common equipment rack 40 comprises a number of equipment shelves 42, 44, 46, including a RF Combiner and power amp shelf (RFC) 42, a Power Supply shelf (PS) 44 and a number of (in this example four) Modem Shelves (MS) 46.
- the RF combiner shelf 42 allows the modem shelves 46 to operate in parallel. If 'n' modem shelves are provided, then the RF combiner shelf 42 combines and amplifies the power of 'n' transmit signals, each transmit signal being from a respective one of the 'n' modem shelves, and amplifies and splits received signals 'n' way so that separate signals may be passed to the respective modem shelves.
- the power supply shelf 44 provides a connection to the local power supply and fusing for the various components in the common equipment rack 40.
- a bidirectional connection extends between the RF combiner shelf 42 and the main central terminal antenna 52, such as an omnidirectional antenna, mounted on a central terminal mast 50.
- This example of a central terminal 10 is connected via a point-to-point microwave link to a location where an interface to the public switched telephone network 18, shown schematically in Figure 1, is made.
- other types of connections e.g., copper wires or optical fibres
- the modem shelves are connected via lines 47 to a microwave terminal (MT) 48.
- a microwave link 49 extends from the microwave terminal 48 to a point-to-point microwave antenna 54 mounted on the mast 50 for a host connection to the public switched telephone network 18.
- a personal computer, workstation or the like can be provided as a site controller (SC) 56 for supporting the central terminal 10.
- the site controller 56 can be connected to each modem shelf of the central terminal 10 via, for example, RS232 connections 55.
- the site controller 56 can then provide support functions such as the localisation of faults, alarms and status and the configuring of the central terminal 10.
- a site controller 56 will typically support a single central terminal 10, although a plurality of site controllers 56 could be networked for supporting a plurality of central terminals 10.
- data connections such as an X.25 links 57 (shown with dashed lines in Figure 3) could instead be provided from a pad 228 to a switching node 60 of an element manager (EM) 58.
- An element manager 58 can support a number of distributed central terminals 10 connected by respective connections to the switching node 60.
- the element manager 58 enables a potentially large number (e.g., up to, or more than 1000) of central terminals 10 to be integrated into a management network.
- the element manager 58 is based around a powerful workstation 62 and can include a number of computer terminals 64 for network engineers and control personnel.
- FIG. 3A illustrates various parts of a modem shelf 46.
- a transmit/receive RF unit (RFU - for example implemented on a card in the modem shelf) 66 generates the modulated transmit RF signals at medium power levels and recovers and amplifies the baseband RF signals for the subscriber terminals.
- the RF unit 66 is connected to an analogue card (AN) 68 which performs A-D/D-A conversions, baseband filtering and the vector summation of 15 transmitted signals from the modem cards (MCs) 70.
- the analogue unit 68 is connected to a number of (typically 1- 8) modem cards 70.
- the modem cards perform the baseband signal processing of the transmit and receive signals to/from the subscriber terminals 20.
- Each modem card 70 in the present example has two modems, and in preferred embodiments there are eight modem cards per shelf, and so sixteen modems per shelf. However, in order to incorporate redundancy so that a modem may be substituted in a subscriber link when a fault occurs, only 15 modems on a single modem shelf 46 are generally used. The 16th modem is then used as a spare which can be switched in if a failure of one of the other 15 modems occurs.
- the modem cards 70 are connected to the tributary unit (TU) 74 which terminates the connection to the host public switched telephone network 18 (e.g., via one of the lines 47) and handles the signalling of telephony information to the subscriber terminals via one of 15 of the 16 modems.
- TU tributary unit
- the wireless telecommunications between a central terminal 10 and the subscriber terminals 20 could operate on various frequencies.
- Figure 4 illustrates one possible example of the frequencies which could be used.
- the wireless telecommunication system is intended to operate in the 1.5-2.5GHz Band.
- the present example is intended to operate in the Band defined by ITU-R (CCIR) Recommendation F.701 (2025-2110MHz, 2200-2290MHz) .
- Figure 4 illustrates the frequencies used for the uplink from the subscriber terminals 20 to the central terminal 10 and for the downlink from the central terminal 10 to the subscriber terminals 20.
- 12 uplink and 12 downlink radio channels of 3.5MHz each are provided centred about 2155MHz. The spacing between the receive and transmit channels exceeds the required minimum spacing of 70MHz.
- each modem shelf supports 1 frequency channel (i.e. one uplink frequency plus the corresponding downlink frequency) .
- CDMA encoding is used to support up to 15 subscriber links on one frequency channel (one subscriber link on each modem) .
- a central terminal has four modem shelves, it can support 60 (15 x 4) subscriber links (ie. 60 STs can be connected to one CT) .
- enhancements to the CDMA encoding technique are provided to increase the number of subscriber links that can be supported by a central terminal.
- the radio traffic from a particular central terminal 10 will extend into the area covered by a neighbouring central terminal 10.
- the radio traffic from a particular central terminal 10 will extend into the area covered by a neighbouring central terminal 10.
- only a limited number of the available frequencies will be used by any given central terminal 10.
- Figure 5A illustrates one cellular type arrangement of the frequencies to mitigate interference problems between adjacent central terminals 10.
- the hatch lines for the cells 76 illustrate a frequency set (FS) for the cells.
- FS frequency set
- FS1 FI, F4 , F7, F10
- FS2 F2 , F5 , F8 , Fll
- FS3 F3 , F6 , F9, F12
- each central terminal 10 can use the four frequency pairs (for the uplink and downlink, respectively) within its cell, each modem shelf in the central terminal 10 being associated with a respective RF channel (channel frequency pair) .
- Figure 5B illustrates a cellular type arrangement employing sectored cells to mitigate problems between adjacent central terminals 10.
- the different type of hatch lines in Figure 5B illustrate different frequency sets.
- the cells are sectored by using a sectored central terminal (SCT) 13 which includes three central terminals 10, one for each sector SI, S2 and S3, with the transmissions for each of the three central terminals 10 being directed to the appropriate sector among SI, S2 and S3. This enables the number of subscribers per cell to be increased three fold, while still providing permanent fixed access for each subscriber terminal 20.
- SCT sectored central terminal
- Arrangements such as those in figures 5A and 5B can help reduce interference, but in order to ensure that cells operating on the same frequency don't inadvertently decode each others data, a seven cell repeat pattern is used such that for a cell operating on a given frequency, all six adjacent cells operating on the same frequency are allocated a unique pseudo random noise (PN) code.
- PN pseudo random noise
- CDMA techniques can be used in a fixed assignment arrangement (ie. one where each ST is assigned to a particular modem on a modem shelf) to enable each channel frequency to support 15 subscriber links.
- Figure 6 gives a schematic overview of CDMA encoding and decoding.
- base band signals for example the user signals for each respective subscriber link
- base band signals are encoded at 80-80N into a 160ksymbols/sec baseband signal where each symbol represents 2 data bits (see, for example the signal represented at 81) .
- This signal is then spread by a factor of 16 using a spreading function 82-82N to generate signals at an effective chip rate of 2.56Msymbols/sec in 3.5MHz .
- the spreading function involves applying a PN code (that is specified on a per CT basis) to the signal, and also applying a Rademacher-Walsh (RW) code which ensures that the signals for respective subscriber terminals will be orthogonal to each other.
- RW Rademacher-Walsh
- a transmitted signal will be subjected to interference sources 88, including external interference 89 and interference from other channels 90. Accordingly, by the time the CDMA signal is received at the receiving antenna 91, the multiple user channel signals may be distorted as is represented at 93.
- a Walsh correlator 94-94N uses the same RW and PN codes that were used for the encoding for each subscriber link to extract a signal (e.g, as represented at 95) for the respective received baseband signal 96-96N. It will be noted that the received signal will include some residual noise. However, unwanted noise can be removed using a low pass filter and signal processing.
- RW codes these being a mathematical set of sequences that have the function of "orthonormality" . In other words, if any RW code is multiplied by any other RW code, the results are zero.
- Table 1 A set of 16 RW codes that may be used is illustrated in Table 1 below:
- the above set of RW codes are orthogonal codes that allow the multiple user signals to be transmitted and received on the same frequency at the same time. Once the bit stream is orthogonally isolated using the RW codes, the signals for respective subscriber links do not interfere with each other. Since RW codes are orthogonal, when perfectly aligned all codes have zero cross-correlation, thus making it possible to decode a signal while cancelling interference from users operating on other RW codes. In preferred embodiments of the present invention, it is desired to provide the central terminal with the ability to support more than 15 subscriber links on each channel frequency, and to achieve this the above set of 16 RW codes has been enhanced. In order to maintain compatibility with former products using the 16 RW codes, it was desirable that any enhancements should retain the same set of 16 RW codes .
- a channel can be selected to operate with the following gross bit rates:
- the manner in which these channelisations are provided differs for the downlink (CT to ST) and uplink (ST to CT) communication paths. This is because it has been realised that different performance requirements exist for the downlink and uplink paths.
- the downlink all signals emanate from a single source, namely the central terminal, and hence the signals will be synchronised.
- the signals will emanate from a number of independent STs, and hence the signals will not be synchronised.
- full rate (160 kb/s) operation is implemented using the basic set of RW codes discussed earlier, but half and quarter rates are achieved through the use of 'Overlay Codes' which comprise RW coded high rate symbol patterns that are transmitted for each intermediate rate data symbol.
- 'Overlay Codes' which comprise RW coded high rate symbol patterns that are transmitted for each intermediate rate data symbol.
- two 2 -bit overlay codes are provide, whilst for quarter rate operation, four 4 -bit overlay codes are provided.
- W generating a signal for transmission, one of the overlay codes, where appropriate, is applied to the signal in addition to the appropriate RW code.
- the incoming signal is multiplied by the channel's PN, RW and Overlay codes.
- the correlator integration period is set to match the length of the Overlay code.
- Overlay codes are used extensively to provide variable rate uplink traffic channels. Overlay codes will also be used to implement downlink control channels, these control channels being discussed in more detail later. However, as mentioned earlier, a different approach is taken for providing flexible channelisations on the downlink traffic channel paths. Downlink traffic channels will operate in high rate, 160 kb/s, mode, with lower data rates of 80 and 40 kb/s being supported by 'Time Division Multiplexing' (TDM) the available bandwidth.
- TDM Time Division Multiplexing'
- TDM timeslot bit numbering will follow the CCITT G.732 convention with bits transmitted in the sequence bit 1, bit 2 ... bit 8.
- Byte orientation is specified per channel as either most significant bit (MSB) first, least significant bit (LSB) first or N/A.
- Figure 7A is a schematic diagram illustrating signal transmission processing stages as configured in a subscriber terminal 20 in the telecommunications system of Figure 1.
- an analogue signal from a telephone is passed via an interface such as two-wire interface 102 to a hybrid audio processing circuit 104 and then via a codec 106 to produce a digital signal into which an overhead channel including control information is inserted at 108.
- elements 102, 104 and 106 may be repeated for each piece of telecommunications equipment.
- the signal At the output of overhead insertion circuit 108, the signal will have a bit rate of either 160, 80 or 40 kbits/s, depending on which channel has been selected for transmission of the signal .
- the resulting signal is then processed by a convolutional encoder 110 to produce two signals with the same bit rate as the input signal (collectively, these signals will have a symbol rate of 160, 80 or 40 KS/s) .
- the signals are passed to a spreader 111 where, if a reduced bit rate channel has been selected, an appropriate overlay code provided by overlay code generator 113 is applied to the signals.
- the signals will be at 160 KS/s irrespective of the bit rate of the input signal since the overlay code will have increased the symbol rate by the necessary amount .
- the signals output from spreader 111 are passed to a spreader 116 where the Rademacher-Walsh and PN codes are applied to the signals by a RW code generator 112 and PN Code generator 114, respectively.
- the resulting signals at 2.56MC/s (2.56 Mega chips per second, where a chip is the smallest data element in a spread sequence) are passed via a digital to analogue converter 118.
- the digital to analogue converter 118 shapes the digital samples into an analogue waveform and provides a stage of baseband power control.
- the signals are then passed to a low pass filter 120 to be modulated in a modulator 122.
- FIG. 7B is a schematic diagram illustrating signal transmission processing stages as configured in a central terminal 10 in the telecommunications system of Figure 1.
- the central terminal is configured to perform similar signal transmission processing to the subscriber terminal 20 illustrated in Figure 7A, but does not include elements 100, 102, 104 and 106 associated with telecommunications equipment.
- the central terminal includes a TDM encoder 105 for performing time division multiplexing where required.
- the central terminal will have a network interface over which incoming calls destined for a subscriber terminal are received.
- the central terminal will contact the subscriber terminal to which the call is directed and arrange a suitable channel over which the incoming call can be established with the subscriber terminal (in preferred embodiments, this is done using the call control channel discussed in more detail later) .
- the channel established for the call will determine the time slot to be used for call data passed from the CT to the ST and the TDM encoder 105 will be supplied with this information.
- the TDM encoder when incoming call data is passed from the network interface to the TDM encoder 105 over line 103, the TDM encoder will apply appropriate TDM encoding to enable the data to be inserted in the appropriate time slot. From then on, the processing of the signal is the same as the equivalent processing performed in the ST and described with reference to Figure 7A, the overlay code generator producing a single overlay code of value ' 1 ' so that the signal output from spreader 111 is the same as the signal input to the spreader 111.
- overlay codes are used to implement downlink control channels, and data relating to such channels is passed from a demand assignment engine (to be discussed in more detail later) over line 107 through switch 109 to the overhead insertion circuit 108, thereby bypassing the TDM encoder 105.
- the processing of the signal is then the same as the equivalent processing performed in the ST, with the overlay code generator providing appropriate overlay codes to the spreader 111.
- the overlay code generator will be controlled so as to produce the desired overlay code, in preferred embodiments, this control coming from the DA engine (to be discussed in more detail later) .
- Figure 8A is a schematic diagram illustrating the signal reception processing stages as configured in a subscriber terminal 20 in the telecommunications system of Figure 1.
- signals received at a receiving antenna 150 are passed via a band pass filter 152 before being amplified in a low noise amplifier 154.
- the output of the amplifier 154 is then passed via a further band pass filter 156 before being further amplified by a further low noise amplifier 158.
- the output of the amplifier 158 is then passed to a mixer 164 where it is mixed with a signal generated by a voltage controlled oscillator 162 which is responsive to a synthesizer 160.
- the output of the mixer 164 is then passed via the I/Q de-modulator 166 and a low pass filter 168 before being passed to an analogue to digital converter 170.
- the digital output of the A/D converter 170 at 2.56 MC/s is then passed to a correlator 178, to which the same Rademacher-Walsh and PN codes used during transmission are applied by a RW code generator 172 (corresponding to the RW code generator 112) and a PN code generator 174 (corresponding to PN code generator 114) , respectively.
- the output of the correlator 178, at 160 KS/s, is then applied to correlator 179, where any overlay code used at the transmission stage to encode the signal is applied to the signal by overlay code generator 181.
- the elements 170, 172, 174, 178, 179 and 181 form a CDMA demodulator.
- the output from the CDMA demodulator (at correlator 179) is then at a rate of either 160, 80 or 40 KS/s, depending on the overlay code applied by correlator 179.
- the output from correlator 179 is then applied to a Viterbi decoder 180.
- the output of the Viterbi decoder 180 is then passed to an overhead extractor 182 for extracting the overhead channel information. If the signal relates to call data, then the output of the overhead extractor 182 is then passed through TDM decoder 183 to extract the call data from the particular time slot in which it was inserted by the CT TDM encoder 105.
- the call data is passed via a codec 184 and a hybrid circuit 188 to an interface such as two wire interface 190, where the resulting analogue signals are passed to a telephone 192.
- elements 184, 188, 190 may be repeated for each piece of telecommunications equipment 192 at the ST.
- the data output by the overhead extraction circuit 182 is data on a downlink control channels, then instead of passing that data to a piece of telecommunications equipment, it is passed via switch 187 to a call control logic 185, where that data is interpreted by the ST.
- a stage of automatic gain control is incorporated at the IF stage.
- the control signal is derived from the digital portion of the CDMA receiver using the output of a signal quality estimator.
- Figure 8B illustrates the signal reception processing stages as configured in a central terminal 10 in the telecommunications system of Figure 1.
- the signal processing stages between the RX antenna 150 and the overhead extraction circuit 182 are the as those within the ST discussed in connection with figure 8A.
- call data output from the overhead extraction circuit is passed over line 189 to the network interface within the CT, whilst control channel data is passed via switch 191 to the DA engine 380 for processing.
- the DA engine is discussed in more detail later.
- Overlay codes and channelisation plans are selected to ensure signal orthogonality - i.e. in a properly synchronised system, the contribution of all channels except the channel being demodulated sum to zero over the correlator integration period.
- uplink power is controlled to maintain constant energy per bit. The exception to this is Low rate which will be transmitted at the same power as a Quarter rate signal .
- Table 2 illustrates the overlay codes used for full, half and quarter rate operations:
- a 10 kb/s acquisition mode which uses concatenated overlays to form an acquisition overlay; this is illustrated in table 3 below:
- Figures 9A and 9B are diagrams illustrating the uplink and downlink delivery methods, respectively, when the system is fully loaded, and illustrate the difference between the use of overlay codes illustrated in figure 9A and the use of TDM as illustrated in Figure 9B .
- overlay codes an RW code is split in the RW space domain to allow up to four sub channels to operate at the same time.
- an RW code is split in the time domain, to allow up to four signals to be sent using one RW code, but at different times during the 125 us frame.
- the last two RW codes, RW14 and RW15 are not used for data traffic in preferred embodiments, since they are reserved for call control and acquisition functions; this will be discussed in more detail later.
- the CDMA channel hierarchy is as illustrated in Figure 10. Using this hierarchy, the following CDMA channelisations are possible:
- FIG 11 is a block diagram of downlink and uplink communication paths between central terminal 10 and subscriber terminal 20.
- a downlink communication path is established from transmitter 200 in central terminal 10 to receiver 202 in subscriber terminal 20.
- An uplink communication path is established from transmitter 204 in subscriber terminal 20 to receiver 206 in central terminal 10.
- telephone communication may occur between a user 208, 210 of subscriber terminal 20 and a user serviced through central terminal 10 over a downlink signal 212 and an uplink signal 214.
- Downlink signal 212 is transmitted by transmitter 200 of central terminal 10 and received by receiver 202 of subscriber terminal 20.
- Uplink signal 214 is transmitted by transmitter 204 of subscriber terminal 20 and received by receiver 206 of central terminal 10.
- Receiver 206 and transmitter 200 within central terminal 10 are synchronized to each other with respect to time and phase, and aligned as to information boundaries.
- receiver 202 in subscriber terminal 20 should be synchronized to transmitter 200 in central terminal 10. Synchronization occurs by performing an acquisition mode function and a tracking mode function on downlink signal 212. Initially, transmitter 200 of central terminal 10 transmits downlink signal 212.
- Figure 12 shows the contents of downlink signal 212.
- a frame information signal 218 is combined with an overlay code 217 where appropriate, and the resultant signal 219 is combined with a code sequence signal 216 for central terminal 10 to produce the downlink 212.
- Code sequence signal 216 is derived from a combination of a pseudo-random noise code signal 220 and a Raderaum-Walsh code signal 222.
- Downlink signal 212 is received at receiver 202 of subscriber terminal 20.
- Receiver 202 compares its phase and code sequence to a phase and code sequence within code sequence signal 216 of downlink signal 212.
- Central terminal 10 is considered to have a master code sequence and subscriber terminal 20 is considered to have a slave code sequence.
- Receiver 202 incrementally adjusts the phase of its slave code sequence to recognize a match to master code sequence and place receiver 202 of subscriber terminal 20 in phase with transmitter 200 of central terminal 10.
- the slave code sequence of receiver 202 is not initially synchronized to the master code sequence of transmitter 200 and central terminal 10 due to the path delay between central terminal 10 and subscriber terminal 20. This path delay is caused by the geographical separation between subscriber terminal 20 and central terminal 10 and other environmental and technical factors affecting wireless transmission.
- receiver 202 After acquiring and initiating tracking on the central terminal 10 master code sequence of code sequence signal 216 within downlink signal 212, receiver 202 enters a frame alignment mode in order to establish the downlink communication path. Receiver 202 analyzes frame information within frame information signal 218 of downlink signal 212 to identify a beginning of frame position for downlink signal 212. Since receiver 202 does not know at what point in the data stream of downlink signal 212 it has received information, receiver 202 must search for the beginning of frame position in order to be able to process information received from transmitter 200 of central terminal 10. Once receiver 202 has identified one further beginning of frame position, the downlink communication path has been established from transmitter 200 of central terminal 10 to receiver 202 of subscriber terminal 20. The structure of the radio frames of information sent over the downlink and uplink paths will now be discussed with reference to figures 13 and 14. In figures 13 and 14, the following terms are used:
- Bn Customer payload 1 x 32 to 2 x 64 Kb/s Dn Signalling Channel, 2 to 16 kb/s OH Radio Overhead Channel
- Figures 13A and 13B show a 125us subframe format, which is repeated throughout an entire radio frame, a frame typically lasting for 4 milliseconds (ms) .
- Figure 13A illustrates the radio frame structures that are used in preferred embodiments for the downlink path.
- Subframe (i) in Figure 13A shows the radio frame structure used for low rate, 10 Kb/s, acquisition mode (Ln-D) during which only the overhead channel is transmitted.
- Subframe (ii) in Figure 13A shows the radio frame structure employed for the call control channel operating in quarter rate, 40 Kb/s, mode (Qn-D)
- subframe (iii) of Figure 13A illustrates the radio frame structure used for traffic channels operating in full rate, 160 kb/s, mode (Fl-D) .
- subframe (i) of Figure 13B shows the radio frame structure used for the uplink path when operating in low rate acquisition or call control mode (Ln-U) .
- Sub- frames (ii) to (iv) show the radio frame structure used for traffic channels when operating in quarter rate mode (Qn- U) , half rate mode (Hn-U) , and full rate mode (Fl-U) , respectively.
- FIG. 14A and 14B show the overhead frame structure employed for various data rates.
- the overhead channel may include a number of fields - a frame alignment word (FAW) , a code synchronization signal (CS) , a power control signal (PC) , an operations and maintenance channel signal (OMC) , a mixed OMC/D-Channel (HDLC) signal (OMC/D) , a channel identifier byte (Ch.ID), and some unused fields.
- FAW frame alignment word
- CS code synchronization signal
- PC power control signal
- OMC operations and maintenance channel signal
- OMC/D mixed OMC/D-Channel
- Ch.ID channel identifier byte
- the frame alignment word identifies the beginning of frame position for its corresponding frame of information.
- the code synchronization signal provides information to control synchronization of transmitter 204 in subscriber terminal 20 to receiver 206 in central terminal 10.
- the power control signal provides information to control transmitting power of transmitter 204 in subscriber terminal 20.
- the operations and maintenance channel signal provides status information with respect to the downlink and uplink communication paths and a path from the central terminal to the subscriber terminal on which the communication protocol which operates on the modem shelf between the shelf controller and the modem cards also extends.
- the OMC/D signal is a combination of the OMC signal and a signalling signal (D) , whilst the Ch. ID signal is used to uniquely identify an RW channel, this Ch. ID signal being used by the subscriber terminal to ensure that the correct channel has been acquired.
- the subscriber terminal will receive downlink traffic channel data at a rate of 160 kb/s.
- the ST will be allocated an appropriate share of the radio overhead.
- TDM mappings are created:
- Rate code ' FI ' indicates full rate
- 'D' indicates that the channel is a downlink channel
- 'Tn/t' indicates that the channel is time division multiplexed between STs
- the D-channel protocol includes an address field to specify which ST is to process the contents of the message.
- the channel structure was illustrated earlier in
- the channel structure is flexible but comprises :
- LAC Link Acquisition Channel
- CRC Call Control Channel
- PTC Priority Traffic Channels
- FIGs 15A and 15B illustrate typical downlink and uplink channel structures that might occur in a loaded system in accordance with preferred embodiments of the present invention.
- some signals may be at 160 kb/s and utilise an entire RW channel.
- An example of such signals would be those sent over fixed assignment links to products which do not support the CDMA enhancements provided by systems in accordance with preferred embodiments of the present invention, as illustrated for RW1 and RW2 in Figure 15A.
- a user may have authority to utilise a whole RW channel, for example when sending a fax, as illustrated by RW12 in Figure 15A.
- TDM can be used on the downlink traffic channels to enable more than one CT to ST communication to take place on the same RW channel during each frame.
- certain channels can be locked to limit interference from other nearby cells, as will be discussed in more detail later.
- Similar channelisations can be achieved for the uplink paths, but as illustrated in Figure 15B, overlay codes are used instead of TDM to enable more than one ST to CT communication to take place on the same RW channel during each frame (as shown in Figure 15B for RW5 to RW11) .
- the channels RW14 and RW15 are reserved as a call control channel and an link acquisition channel, respectively, and overlay codes are employed on these channels, irrespective of whether the path is a downlink or an uplink path. These two channels will be discussed in more detail below.
- LAC Link Acquisition Channel
- Each CT Modem Shelf will maintain a database holding the serial numbers of all STs that could possibly be supported by that CT.
- the state of each ST will recorded with top level states as follows:
- Transition states will also be defined.
- An ST is considered cold if the ST is newly provisioned, the CT has lost management communications with the ST or the CT has been power cycled.
- the CT Over the LAC, the CT broadcasts individual ST serial numbers and offers an invitation to acquire the LAC uplink.
- Cold uplink acquisition will be carried out on the Link Acquisition Channel at low rate.
- the CT will invite specific ST's to cold start via the management channel .
- the appropriate acquisition overlay will be selected, and acquisition will be initiated.
- 'Rapid' downlink RW channel switching may be supported at rates other than Ln-D. Rapid means that coherent demodulation is maintained, and only convolutional decoding and frame synchronisation processes need be repeated.
- the ST On acquisition, management information will be exchanged.
- the ST will be authenticated and allocated a short ST_identifier (between 12 and 16 bits) which will be used for subsequent addressing.
- the ST uplink will operate for long enough for the uplink to be parametised by the ST in terms of code phase and transmit power. These parameters will be used by the ST for subsequent warm start acquisitions and will also be held by the CT to allow the CT to force a cold ST to warm start .
- the ST On successful completion of net entry, the ST will be placed in the idle state and instructed to cease uplink communications and move to the Call Control Channel (CCC) (RW14 in preferred embodiments) .
- CCC Call Control Channel
- the time taken for net entry to be achieved can be monitored, and the following techniques can be used to decrease net entry time if desired: (i) Prioritise so that high GOS (Grade Of Service) users are offered net entry first.
- GOS Gram Of Service
- Each poll comprises a broadcast invitation for an addressed
- a Management Poll may fail for one of the following reasons :
- the ST is or has been powered down. An EM alarm may be flagged if this persists and the database for that ST should be marked cold.
- the Net Entry process will follow, (ii) The ST is either making a call or in the process of making a call.
- the poll cycle may be suspended and management communications effected on the appropriate traffic channel.
- the basic acquisition process from the ST side is as follows; (i) Switch the downlink (receiver) circuitry to 10 kb/s rate, and select the appropriate Traffic Channel RW and Overlay codes. Acquisition of the TC downlink is limited to achieving frame alignment, (ii) The downlink PC/CS channel will be decoded to create a busy / idle flag. If PC/CS reports busy, then this means that another ST is using that traffic channel and the ST aborts the acquisition process, (iii) Switch uplink to 10 kb/s rate, and select the appropriate Traffic Channel RW and Overlay codes. Enable the ST transmitter at a level of nominal full rate power minus 18 dB .
- the uplink should acquire at nominal full rate power minus 6 dB . Uplink acquisition is aborted if maximum transmit level is reached and PC/CS continues to report idle.
- PC/CS reports busy.
- the ST may have genuinely acquired the traffic channel, or instead may be observing PC/CS go busy because another ST has acquired the traffic channel.
- the ST is sent an authentication request and responds with it's
- the CT grants uplink access by returning the ST_identifier.
- the ST aborts the acquisition process if the returned ST_identifier is not recognised (ie. is not the ST_identifer that it sent) .
- This authentication process arbitrates between two STs contending for outgoing access and it also keeps STs from acquiring TCs that have been reserved from incoming access.
- a number of TCs will be reserved for incoming calls, and incoming call processing is as follows: (i) Check the CT database - if the ST is in the call_in_progress state the call is rejected.
- An incoming call setup message is broadcast over the CCC to inform the addressed ST of the incoming call and specify the TC on which to receive the call. If no TC is available but the CT forms part of a Service Domain, then the incoming call setup message is sent with a null TC otherwise the call is rejected. Service domains will be discussed in more detail later.
- the incoming call setup message is repeated a number of times .
- the ST attempts uplink acquisition. The ST listens to the downlink and keeps trying for uplink acquisition until the CT sends a message to the ST to return the
- the ST will also run a timer to return it back to the CCC in the event of an incoming call failing to complete.
- Outgoing calls are supported by allowing slotted random access to the TC uplinks.
- the outgoing call processing is as follows:
- the ST picks a channel from the free list at random.
- the algorithm that the ST uses to pick a channel will need to be specified in the free list. For example, the ST may be required to always choose from a pool of minimum bandwidth channels so that high bandwidth channels remain available for high GOS users. Alternatively the ST may be allowed to choose any channel regardless of bandwidth for minimum blocking. In preferred embodiments, STs will not choose low bandwidth channels and negotiate the rate up.
- the ST may be unable to acquire a TC by the time the call setup timer expires.
- the ST may in such cases cease attempting outgoing access and generate congestion tone.
- Priority calling is complicated because the ST must: (i) Capture and decode dialled digits.
- the CT will publish Directory Numbers (DNs) for a number of emergency services over the CCC.
- DNs Directory Numbers
- the ST will attempt uplink access according to the normal algorithms. If the outgoing access is successful then the customer is able to dial as normal . All dialled digits are check against the emergency DN list so that calls may be categorised normal or priority at the CT . (iii) If congestion tone is returned the customer is allowed to dial the emergency number into the ST. If the ST detects an emergency DN sequence then uplink access via the Priority Traffic Channel (PTC) is attempted. (iv) On PTC acquisition, the ST relays the dialled digit sequence to the CT for dialling into the PSTN, (iv) The CT converts the PTC to a TC and reallocates another TC to become the PTC, dropping a normal call in progress if necessary. Interference Limiting (Pool Sizing)
- the central terminal is provided with the ability to trade traffic for
- the CT will control the number of Traffic Channels to minimise access noise.
- TCs will be classified as: (i) Busy - carrying traffic;
- Busy TC If a Free TC is available, it is converted to a new Access TC . If there are no Free TCs then the
- the CT will monitor the Busy TC downlink and uplink soft error counts in an attempt to establish link quality. If the CT records a lower than average soft error count and long call setup times are being recorded, a Locked TC may be converted to a Free TC.
- a Free or Access TC may be converted to a Locked TC .
- Figure 17 illustrates how the central terminal performs the above interference limiting function.
- encoder 325 encodes the data for transmission over the wireless link 300 to the subscriber terminal 20.
- the decoder 326 decodes the data, and passes the decoded user data over line 328 to the subscriber telecommunications equipment.
- the decoder 326 decodes the data, it is able to establish a bit error rate (BER) estimate 330 associated with the signal transmission over the wireless link 300, which can be passed to the multiplexer 332 for combining with other signals, such as those from a call control function 336 or user data on line 338, before being passed to an encoder 334.
- BER bit error rate
- the BER estimate is encoded and passed on the OMC channel over the wireless link 310 to the decoder 340 within the central terminal modem 320.
- the signal passes to the multiplexer 345, where the BER estimate from the subscriber terminal is detected and passed over line 355 to the dynamic pool sizing function 360. Further, as at the subscriber terminal 20, the decoder
- the dynamic pool sizing function 360 is provided on the CT modem shelf 302, and receives BER estimates from each of the modems on that shelf indicated by the lines entering the bottom of the dynamic pool sizing function 360. In addition to BER estimates, grade of service (GOS) data is obtained from two sources.
- GOS grade of service
- the call control function 336 will note how readily it is able to establish traffic channels for transmitting and receiving data, and from this can provide a GOS estimate to the multiplexer 332 for encoding by the encoder 334 for subsequent transmission over the wireless link 310 to the central terminal modem 320.
- the GOS estimate is decoded by decoder 340, passed through multiplexer 345, and then the GOS estimate is passed over line 355 to the dynamic pool sizing function 360.
- incoming call information to the central terminal is provided over the concentrated network interface 390 to the DA engine 380.
- the DA engine 380 includes a call control function, similar to the call control function 336 in each of the subscriber terminals 20, for each of the modems on the modem shelf.
- the call control functions within the DA engine 380 are also able to provide GOS estimates for incoming calls, and these GOS estimates are passed over line 395 to the dynamic pool sizing function 360.
- the management system 370 within the element manager will have connected to the central terminal, and provided the dynamic pool sizing function 360 within the modem shelf with data identifying a BER goal, a GOS goal, and a pool size limit (i.e. the number of channels that can be used for data traffic) .
- the dynamic pool sizing function 360 then compares this data from the management system with the actual BER, actual GOS, and the actual pool size information that it receives.
- a suitable algorithm can be provided within the dynamic pool sizing function 360 to determine, based on this information, whether pool sizing is appropriate.
- the dynamic pool sizing function 360 may be arranged to send a pool sizing request to the demand assignment engine 380.
- the demand assignment engine 380 provides modem enable signals over lines 400 to each of the modems on the CT modem shelf. If the dynamic pool sizing function 360 has requested that the DA engine 380 perform pool sizing, then the DA engine 380 can disable one or more of the modems, this causing the interference, and hence the actual BER, to be reduced.
- the DA engine is also responsible, in preferred embodiments, for providing the encoders 325 with instructions on which set of overlay codes or how many TDM slots to be used for signals to be transmitted to the STs 20.
- the dynamic pool sizing function can store the BER and GOS information received in the storage 365, and periodically may pass that data to the management system 370 for analysis. Further, if the system is unable to attain the BER or GOS goal with the allocated pool size, the dynamic pool sizing function can be arranged to raise an alarm to the management system. The receipt of this alarm will indicate to personnel using the management system that manual intervention may be required to remedy the situation, eg by the provision of more central terminal hardware to support the STs .
- the CDMA approach used in preferred embodiments exhibits the property that the removal of any of the orthogonal channels (by disabling the modem) will improve the resistance of the other channels to interference.
- a suitable approach for the demand assignment engine 380 upon receipt of pool sizing request from the dynamic pool sizing function 360, is to disable the modem that has the least traffic passing through it.
- FIG. 18 shows an arrangement where omni antennae are used to provide the entire cell with four frequency channels, eg
- Figure 18 (ii) shows an arrangement where sectored antennae are used to provide six separate sectors within a cell, each sector being covered by two frequency channels.
- Figure 18 (iii) shows an alternative arrangement where three sectored antennae are used to divide the cell in to three sectors, each sector being covered by a separate frequency channel, and then an omni antenna is used to provide an 'umbrella' coverage for the entire cell, this coverage employing a frequency channel different to the three frequency channels used by the sectored antennae.
- CT shelf synchronisation For the system to work effectively, the STs must be able to switch channels quickly, and fast channel switching necessitates that CT shelf synchronisation be provided at the following levels:
- an ST On installation, an ST will be programmed with an RF channel and PN code, these codes specifying the ST's initial home channel.
- a service domain controller 400 is preferably provided to act as an interface between the exchange connected to the service domain controller over path 405 and a number of central terminals 10 connected to the service domain controller over paths 410.
- the central terminals connected to the service domain controller form a 'service domain' of central terminals that may be used by a subscriber terminal 20 for handling communications.
- the service domain controller 400 is used to provide each CT 10 with appropriate information about the other CTs within the service domain.
- Each CT can then broadcast a 'Service Domain' message comprising a list of RF frequencies and CT Identifiers that form a Service Domain to be used by the STs for subsequent RF switching functions.
- the ST then stores this information for future reference when establishing a link with one of the CTs. It is preferable for each CT to broadcast the service domain message since an ST may be listening to any of the CTs at the time that the message is broadcast.
- Each CT database will hold an entry for every ST located within the Service Domain.
- Each database entry describes how the CT views it's relationship with the ST and may be marked as : (i) Primary service provider - the CT is the ST's home channel. All management communication with an ST is via it's home CT. (ii) Supplying backup service - the CT is providing service to the ST. (iii) Available for backup service - the CT will provide service to the ST if required. It should be noted that the ST need not switch to an entirely different CT, but can instead switch to a different CT shelf (and hence different RF frequency channel) within the same CT.
- the ST will typically switch to a different CT, since some errors experienced by one CT shelf may also affect other shelves within the same CT, and so for fault tolerance (described in more detail below) , it is preferable for the ST to switch to a separate CT.
- Database consistency across CT shelves is preferably supported through the service domain controller 400. Database consistency needs to be real-time so that an ST entering the network is allowed full Service Domain access immediately (the Service Domain message is broadcast to all STs, and so a new ST will expect access across the full Service Domain) .
- Incoming access via backup CTs requires some function to be provided to broadcast duplicate incoming call setup messages to all CTs that form a Service Domain. Preferably this is handled by the service domain controller 400, which forwards incoming call setup messages to each CT operating in the service domain. All CTs will allocate Access_In Traffic Channels and relay the incoming call setup message via the Call Control Channel. On successful uplink access, one CT will respond to the service domain controller with a call accepted message, the other CTs will eventually respond with call setup failed messages. Outgoing access via a backup CT is similar to normal outgoing access. Another job which can be performed by the service domain controller is to assist the element manager 58 in reconfiguring equipment in the event of a fault. For example, if one CT is taken out of commission because of a fault, a different CT can be brought 'on-line', and the service domain controller can provide that new CT with the necessary information about the other CTs in the service domain .
- Figure 19B illustrates those elements of the subscriber terminal used to implement RF channel switching.
- the radio subsystem 420 which incorporates the transmission and reception signal processing stages, will pass any data received on the call control channel over line 425 to the message decoder 430. If the decoder 430 determines that the data on the call control channel forms a service domain message, then this is passed over line 435 to the channel selection controller 440, where the information within the service domain message is stored in storage 445.
- the message decoder identifies the data as a 'free list' identifying the available traffic channels on a particular RF frequency, then this data is passed to the call control function 336 and the channel selection controller 440 over path 450.
- the call control function 336 stores the free list in the storage 445 for subsequent use by the call control function 336 and the channel selection controller 440.
- the message decoder 430 determines that the data forms an incoming call setup message, then that information is supplied over line 455 to the call control function 336 and the channel selection controller 440 for processing.
- the incoming call setup message will typically specify a TC on the current frequency channel which should be used to access the incoming call, and the channel selection controller will attempt to establish a link on that TC.
- the channel selection controller will in such cases instruct the radio sub-system 420 over line 465 to use the current frequency channel to establish the required link. If, on the other hand, the traffic channel specified in the call setup message is 'null', the channel selection controller has the option to change RF frequency using the information stored in storage 445 about the other CTs in the service domain.
- a link operating status signal can be supplied over line 470 from the radio sub-system. This signal will give an indication of the radio link quality, and may be a simple 'OK' or 'failed' indication, or alternatively may include extra information such as BER values for the link. This information can be used by the channel selection controller to determine whether a particular frequency channel should be used or not .
- a line 460 is provided between the call control function 336 and the channel selection controller 440.
- the call control function 336 may choose an access-out channel from the free list in storage 445, and instruct the channel selection controller over line 460 to attempt acquisition of that channel.
- the following examples indicate how the above described structure may be used to perform channel switching in particular circumstances. RF Channel Switching for Fault Tolerance Should one RF channel suffer complete loss of downlink, the following process takes place in preferred embodiments :
- the ST will attempt downlink re-acquisition for a period of time, say 20 seconds.
- the EM 58 may use the service domain controller 400 to reconfigure the
- a fault that does not result in complete loss of downlink signal will not result in RF channel switching 'en mass'. Rather, a fault may result in excessive or total call blocking, as discussed below.
- the CT will specify a null TC.
- the channel selection controller 440 of the ST will in such cases switch to the next RF channel from the Service Domain information in storage 445 and monitor the Call Control Channel .
- the ST receives a call setup message with a valid TC, then the call is processed as normal,
- the ST downlink preferably switches back to the home CT .
- Traffic load balancing is, in preferred embodiments, provided by static configuration via the EM 58. Call blocking and setup time statistics may be forwarded to the
- Frequency diversity is, in preferred embodiments, provided by static configuration via the EM 58. Radio link statistics may be forwarded to the EM where an operator may decide to move an ST to another RF channel.
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Abstract
Description
Claims
Priority Applications (6)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
PL97334213A PL334213A1 (en) | 1996-12-20 | 1997-12-18 | Interference control in a cell a radio telecommunication system |
CA002273342A CA2273342A1 (en) | 1996-12-20 | 1997-12-18 | Controlling interference in a cell of a wireless telecommunications system |
EP97952387A EP0953268A2 (en) | 1996-12-20 | 1997-12-18 | Controlling interference in a cell of a wireless telecommunications system |
AU56006/98A AU5600698A (en) | 1996-12-20 | 1997-12-18 | Controlling interference in a cell of a wireless telecommunications system |
BR9713601-8A BR9713601A (en) | 1996-12-20 | 1997-12-18 | Control of interference in a cell of a wireless telecommunications system |
NO992983A NO992983L (en) | 1996-12-20 | 1999-06-17 | Control of interference in a cell in a wireless telecommunication system |
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
GB9626568.1 | 1996-12-20 | ||
GB9626568A GB2320648A (en) | 1996-12-20 | 1996-12-20 | Controlling interference in a cell of a wireless telecommunications system |
Publications (2)
Publication Number | Publication Date |
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WO1998031176A2 true WO1998031176A2 (en) | 1998-07-16 |
WO1998031176A3 WO1998031176A3 (en) | 1998-12-03 |
Family
ID=10804806
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PCT/US1997/022797 WO1998031176A2 (en) | 1996-12-20 | 1997-12-18 | Controlling interference in a cell of a wireless telecommunications system |
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US (1) | US6195327B1 (en) |
EP (1) | EP0953268A2 (en) |
AU (1) | AU5600698A (en) |
BR (1) | BR9713601A (en) |
CA (1) | CA2273342A1 (en) |
CZ (1) | CZ222099A3 (en) |
GB (1) | GB2320648A (en) |
ID (1) | ID21983A (en) |
NO (1) | NO992983L (en) |
PL (1) | PL334213A1 (en) |
TR (1) | TR199901415T2 (en) |
WO (1) | WO1998031176A2 (en) |
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- 1997-12-18 EP EP97952387A patent/EP0953268A2/en not_active Withdrawn
- 1997-12-18 PL PL97334213A patent/PL334213A1/en unknown
- 1997-12-18 CZ CZ992220A patent/CZ222099A3/en unknown
- 1997-12-18 TR TR1999/01415T patent/TR199901415T2/en unknown
- 1997-12-18 AU AU56006/98A patent/AU5600698A/en not_active Abandoned
- 1997-12-18 ID IDW990554A patent/ID21983A/en unknown
- 1997-12-18 CA CA002273342A patent/CA2273342A1/en not_active Abandoned
- 1997-12-18 BR BR9713601-8A patent/BR9713601A/en not_active IP Right Cessation
- 1997-12-18 WO PCT/US1997/022797 patent/WO1998031176A2/en not_active Application Discontinuation
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1999
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Also Published As
Publication number | Publication date |
---|---|
GB9626568D0 (en) | 1997-02-05 |
WO1998031176A3 (en) | 1998-12-03 |
ID21983A (en) | 1999-08-19 |
US6195327B1 (en) | 2001-02-27 |
EP0953268A2 (en) | 1999-11-03 |
BR9713601A (en) | 2000-04-04 |
CZ222099A3 (en) | 1999-11-17 |
AU5600698A (en) | 1998-08-03 |
PL334213A1 (en) | 2000-02-14 |
CA2273342A1 (en) | 1998-07-16 |
NO992983D0 (en) | 1999-06-17 |
TR199901415T2 (en) | 1999-08-23 |
GB2320648A (en) | 1998-06-24 |
NO992983L (en) | 1999-08-19 |
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