Pulse or digital communications – Spread spectrum – Direct sequence
Reexamination Certificate
2001-09-25
2004-08-03
Burd, Kevin M. (Department: 2631)
Pulse or digital communications
Spread spectrum
Direct sequence
Reexamination Certificate
active
06771692
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates generally to Code Division Multiple Access communications. Particularly, the present invention relates to time tracking received signals in a non-negligible multipath spacing environment.
2. Description of the Related Art
Code Division Multiple Access (CDMA) communications systems use base stations coupled to directional antennas that are typically located in the center of a cell and broadcast into sectors of the cell. The cells are located in major metropolitan areas, along highways, and along train tracks to allow consumers to communicate both at home and while traveling.
FIG. 1
illustrates a block diagram of a typical CDMA base station. The user data is input to a modulator (
101
) that performs the CDMA modulation prior to transmission on the single antenna (
105
). The CDMA modulation technique is well known in the art.
The base station transmits a pilot channel that is received by a mobile station. The pilot channel, comprised of symbols, contains no information. The mobile station uses the pilot channel as a reference signal for time, frequency, phase, and signal strength.
Mobile stations are comprised of RAKE receivers. A conventional RAKE receiver operates on received signals with correlators known as “fingers”. Using the knowledge of complex channel coefficients of each desired multipath component, the RAKE receiver coherently combines finger outputs.
A block diagram of a typical RAKE receiver is illustrated in FIG.
2
. For purposes of clarity, only one finger of the receiver is shown. The receiver is comprised of an antenna (
201
) that receives the signal for conversion from the received radio frequency-to-baseband frequency (
205
). The base band data is a digital data stream.
An initial time delay, &tgr;, is chosen (
210
) and the digital data stream is despread by multiplying (
215
) it with the original spreading sequence combined with a Walsh code. This is referred to as c
d
(n).
The despread signal is correlated by summing (
220
) it over a symbol time (64 chips). The complex signal output from the correlator is multiplied (
225
) with an estimate of the pilot signal, {circumflex over (P)}, in order to rotate the phase of the input signal. This step outputs the demodulated data.
In parallel with the demodulation at time &tgr;, the digital data stream is also demodulated half a chip prior to &tgr; and half a chip after &tgr; in order to generate a more accurate &tgr;. It would be best to sample the waveform at the peak during the on-time sample. However, since this cannot always be accomplished, an early sample is taken approximately half a chip time before the on-time sample and a late sample is taken approximately half a chip time after the on-time sample.
After the ±0.5 chip delay blocks (
230
and
235
), the delayed digital data streams are multiplied (
240
and
245
) with a combination of the same spreading sequence used in the demodulation path and the pilot Walsh code. This is referred to as c
p
(n). These signals are correlated (
250
and
255
) and the magnitude of each signal is then squared (
260
and
265
).
The squared magnitudes are subtracted (
270
) to find the difference between the two energies. If the difference is zero, the initial estimate for &tgr; was accurate. If the difference is other than zero, this error is input to a time tracking loop (
275
) to generate a new estimate &tgr;. Each finger tracks its assigned signal path using the time tracking loop (
275
) by controlling the finger's location with respect to time.
The above-described receiver performs adequate time tracking if the single base station antenna of
FIG. 1
is used. However, if the base station uses antenna diversity, as illustrated in
FIG. 3
, time tracking becomes more complex in a non-negligible multipath spacing environment.
FIG. 3
illustrates a typical prior art base station where the main data signal is input to a multiplexer (
301
) before being modulated (
305
and
310
). The multiplexer (
301
) switches the data between two or more modulation paths (
305
and
310
). Each modulation path (
305
and
310
) is coupled to a separate antenna (
315
and
320
).
The antennas are typically geographically separated such that the received signal at the mobile station has approximately the same time delay with independent fading characteristics. The most common methods for multiplexing data at the base station are Orthogonal Transmit Diversity and Space Time Spreading.
The Orthogonal Transmit Diversity scheme alternates the transmitted data between the transmit antennas such that each antenna is transmitting a different data signal that is a subset of the main data signal. For example, a first symbol of the main data signal is transmitted on the first antenna, a second symbol is transmitted on the second antenna, and a third symbol is transmitted on the first antenna. In this manner, if the mobile station loses data from one of the antennas, it only loses every other symbol and an error correction routine can correct for the loss.
The Space Time Spreading scheme transmits some information about each data symbol on both antennas. This scheme assumes that the mobile station will be in contact with at least one of the antennas at all times and, therefore, will continue to receive uninterrupted data.
A problem occurs when a mobile station's receiver has to time track on the signals from both base station transmit antennas, and the multipath spacing from one or both of these antennas is non-negligible (e.g., multipath spacing is less than 1.5 chips). There is a resulting need for a receiver that can time track in a non-negligible multi-path environment having antenna diversity.
SUMMARY OF THE INVENTION
The present invention encompasses a method for offset time tracking in a non-negligible multipath spacing environment in which an antenna diversity system is operating. The antenna diversity system comprises a plurality of antennas that each transmits a signal to a mobile station. In one embodiment, the transmitted signals are different functions of the same data. In an alternate embodiment, the transmitted signals are alternating portions of a main signal.
The time tracking is accomplished by generating updated time offsets in response to an average time error signal or by allowing the demodulating elements to independently time track the signals from each antenna. The embodiment used depends on whether the diversity antennas are transmitting using Space Time Spreading or Orthogonal Transmit Diversity.
In one embodiment, the method demodulates, based on one offset, each of the plurality of signals received from the base station's diversity antennas. A time error signal is then calculated from each of the demodulated signal's pilot signals that are sampled prior to the offset and subsequent to the offset. Based on the time error signals, an average time error signal is generated. An updated time offset is then calculated with a time tracking loop in response to the average time error signal.
In another embodiment, the received signals are demodulated using a different offset for each received signal. In this case, each of the receiver's demodulating elements independently track the received signals with two separate time tracking loops.
REFERENCES:
patent: 5764687 (1998-06-01), Easton
patent: 6269075 (2001-07-01), Tran
patent: 6345078 (2002-02-01), Basso
patent: 2003/0128745 (2003-07-01), Sourour et al.
patent: 0024133 (2000-04-01), None
Weerackody V, “Diversity for the direct-sequence spread spectrum system using multiple transmit antennas” ICC, Geneva, (1993) vol. 3:23, pp. 1775-1779.
Butler Brian K.
Ekvetchavit Thunyachate
Patel Shimman
Rick Roland Reinhard
Subrahmanya Parvathanathan
Brown Charles D.
Burd Kevin M.
Pappas George C.
Qualcomm Incorporated
Wadsworth Philip R.
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