Multiplex communications – Communication over free space – Combining or distributing information via code word channels...
Reexamination Certificate
1998-05-13
2002-07-16
Kizou, Hassan (Department: 2662)
Multiplex communications
Communication over free space
Combining or distributing information via code word channels...
C370S335000, C370S441000, C375S130000, C375S140000, C455S065000
Reexamination Certificate
active
06421334
ABSTRACT:
FIELD OF THE INVENTION
The present invention relates to communication systems and in particular relates to the time alignment of uplink CDMA signals.
BACKGROUND OF THE INVENTION
Communication systems employing Code Division Multiple Access (CDMA), signals between a base station and a subscriber are transmitted over a frequency band of the particular communication channel with a particular subscriber spreading code. That is to say the signals in the communication channel for a particular frequency band of the communication channel are separated by these particular spreading codes. These particular subscriber spreading codes are preferably orthogonal with respect to each other such that a cross correlation between time aligned spreading codes is 0.
The orthogonality factor (OF) is a measure of how badly a multi-path channel degrades with the orthogonality of signals. An OF of 0 means that the signals remain completely orthogonal. An OF of 1 means that orthogonality is completely lost and communication performance would be unchanged if random sequences were transmitted rather than orthogonal sequences. A consequence of OF is that intra-cell multiple access interference (MAI) in a system employing orthogonal transmitted sequences will be reduced relative to that of a reference system employing random sequences.
In CDMA communications, individual transmissions are maintained orthogonal with respect to other transmissions on the same frequency by coding each transmission with a direct sequence pseudo-random (PN) code produced by a chip code generator which is supplied to a spread spectrum modulator along with the intermediate frequency (IF) from an oscillator. CDMA allows multiple simultaneous signals which completely overlap in time and frequency. Despite this overlap, the number of spreading codes allows each signal to be detected separately, with limited interference from the other signals. The level of interference is further reduced if orthogonal codes are used, and the channel OF is low. The channel OF can be minimised through time alignment of the strongest path.
The use of orthogonal sequences offers benefits in cases where different users symbols are received with time alignment. For flat channels, time aligning signals at the receiver results in perfect orthogonality and hence no intra-cell interference. In the more realistic case, where channels exhibit dispersive multi-path characteristics (i.e. the channels are not flat), each separate multi-path component will interfere with each other component which has a different delay. In this case it is only possible, in general, to align a single component from each signal, and orthogonality will be partially lost due to the interference between non-aligned terms. The OF achieved in any scenarios depend both upon the channels involved and the relative timing between users signals.
Referring now to
FIG. 1
there is shown a simple situation where only a single multi-path component from each user can be simultaneously aligned (and each component is separated in time by at least one chip duration). In this situation, alignment of the strongest component of each profile will result in the lowest value achievable with those channels. The spacing of the multi-paths is such that only a single component from each channel can be aligned simultaneously.
In the three cases shown in
FIGS. 1
a-c,
the different time alignments for the same two channel power delay profiles vary from no orthogonality in case a i.e. OF=1.0 to a case where the OF=0.85, as shown in case b. In case c the strongest component of each channel is aligned thus removing the largest cross interference term and reducing the OF still further to OF=0.55. In this example, it is only possible to align a single multi-path component between each pair of users and the optimum timing alignment between the users is simple to determine; the strongest multi-path component of each user's signal should arrive simultaneously. In practice it is unlikely that more than a single multi-path component from each user's channel can be aligned simultaneously. In addition, when fractional-chip delays between components are present, performance is also dependent upon the set shape of the chip wave form.
Referring now to ITU-A and ITU-B, (International Telecommunications Union) channel models, which were developed for mobile systems, each path independently fades according to a Rayleigh distribution. For an IS95 system, for example, the chip period is 813.8 ns, and for a wide band system with three times the bandwidth it is 271.3 ns. The channel power delay profiles are provided in table 1 and it can be seen that at both chip rates, both channels have components which are not separately resolvable.
FIGS. 2 and 3
demonstrate the respective A and B channel models (for the purposes of particular example, the individual path powers are held equal to their mean values, but the phases are allowed to vary randomly). Each trace is for a different set of phases of the multi-path components. The peaks in the band limited power delay profile do not directly correspond in time with those of any of the multi-path components for the non-band limited channel. For the ITU-A channel, most of the channel power is contained in the first tap and the remaining significant taps have very short delays. It can be seen that even if the power of the individual multi-path is constant, relative phase changes between them can cause the resultant power to vary significantly, even when one of the components is much stronger than the other. For the ITU-B channel, the first two paths are of comparable strength and are closely spaced relative to the chip duration. If they have opposite phases then they will combine destructively resulting in very low output power for time delays in that region. The second and fourth traces have opposite phases for the first two paths whereby the timing at which maximum output occurs is approximately a quarter of the third and fourth components respectively. At the ITU-B wide band chip rate, the spacing between the first two components is approximately three quarters of a chip duration. The power delay profile which has a single peak at the IS 95 chip rate can split into two separate peaks at different timings as the phases are varied in the wide band case.
OBJECT OF THE INVENTION
The present invention seeks to provide timing alignment between orthogonal CDMA channels. The present invention also seeks to provide a technique which allows very rapid and precise control of signal time alignment, with a minimum of signalling overhead. The invention further seeks to provide a CDMA communications arrangement for fixed wireless access systems.
STATEMENT OF THE INVENTION
In accordance with a first aspect of the present invention, there is provided a method of determining timing offsets in a CDMA communications link between a base station and a subscriber station, the method comprising the steps of: transmitting a signal by the subscriber using a default timing offset; receiving such signal by the base station and detecting the various multipath components using a Rake receiver, and; when the base station determines that a subscriber station needs to change its timing alignment, it transmits to the subscriber a message identifying a particular timing offset selected from a set of predetermined offsets which the subscriber should use.
The set of predetermined offsets can be stored in a look-up table. The look-up table can be in the form of a volatile storage medium. The look-up table can be in the form of a non-volatile storage medium. The default timing offsets can be those that have been used on a most recent transmission; those that have been used most frequently by the system or predetermined offsets.
Adjustment of the timing can be carried out by the insertion of a short signal into each frame to determine which offset should be selected. Time alignment commands transmitted by the base station may be transmitted once for each transmission or can be transmitted by the b
Kizou Hassan
Lee Mann Smith McWilliams Sweeney & Ohlson
Logsdon Joe
Nortel Networks Limited
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