Pulse or digital communications – Testing
Reexamination Certificate
2000-07-31
2004-03-02
Le, Amanda T. (Department: 2634)
Pulse or digital communications
Testing
C375S349000, C370S252000, C324S076140, C324S613000, C455S065000, C455S067700
Reexamination Certificate
active
06700929
ABSTRACT:
FIELD OF THE INVENTION
The present invention generally relates to direct-sequence spread spectrum (DSSS) communications systems, and particularly relates to characterizing multipath propagation characteristics in DSSS receivers.
BACKGROUND OF THE INVENTION
In wireless communications systems, successfully extracting transmitted information from a received signal oftentimes requires overcoming significant levels of interference. Multipath interference represents one type of received signal interference that can be particularly problematic in certain types of wireless communications systems. For example, wireless LANs are typically employed in indoor environments that commonly include partitioned walls, furniture, and multiple doorways, along with various metallic and non-metallic building features. In these environments, transmitted signals follow multiple transmission paths of differing lengths and attenuation. Consequently, a receiver in such an environment receives multiple, time-offset signals of differing signal strengths. These multiple versions of the same transmit signal are termed “multipath signals.”
The effect of multipath signals on DSSS receiver performance depends upon the particulars of the communications system in question. For example, in certain types of DSSS communications systems, multipath signals can actually improve receiver signal-to-noise ratio. To understand this phenomenon, it is helpful to highlight a few basic aspects of DSSS communications. DSSS transmitters essentially multiply an information signal by a pseudo-noise (PN) signal—a repeating, pseudo-random digital sequence. Initially, the information signal is spread with the PN signal, and the resultant spread signal is multiplied with the RF carrier, creating a wide bandwidth transmit signal. In the general case, a receiver de-spreads the received signal by multiplying (mixing) the incoming signal with the same PN-spread carrier signal. The receiver's output signal has a maximum magnitude when the PN-spread signal exactly matches the incoming received signal. In DSSS systems, “matching” is evaluated based on correlating the incoming PN-sequenced signal with the receiver's locally generated PN-sequenced signal.
The spreading code (PN code) used by the transmitter to spread the information signal significantly influences the effects of multipath signals on receiver performance. DSSS transmissions based on a single spreading code with good autocorrelation properties (or on a small set of orthogonal spreading codes) allow the receiver to selectively de-correlate individual signals within a multipath signal relatively free of interference from the other signals within the multipath signal. By adjusting the PN-sequence offset used to generate its local PN despreading signal, the receiver can time-align (code phase) its despreading circuitry with any one of the multipath signals it is receiving. If the spreading/despreading PN code has good autocorrelation and cross-correlation properties, the receiver can recover the transmitted data from any one of these multipath signals without undue interference. Of course, it may be preferable to use only the strongest multipath signal(s) for information recovery.
Indeed, conventional RAKE receivers used in Code-Division Multiple Access (CDMA) digital cellular telephone systems exploit the above situation. CDMA transmissions use a relatively long, fixed spreading code for a given receiver and transmitter pair, which results in very favorable auto- and cross-correlation characteristics. RAKE receivers are well known in the art of digital cellular receiver design. A RAKE receiver includes multiple, parallel “RAKE fingers.” Each RAKE finger can independently synchronize with and de-spread a received signal.
By synchronizing the multiple RAKE fingers to the strongest received multipath signals (those with the highest correlation values), the RAKE fingers lock on to the strongest multipath signals. Because of the excellent correlation properties of the CDMA spreading codes, each RAKE finger synchronizes with and de-spreads one of the multipath signals relatively free from interference associated with the other multipath signals. Thus, each RAKE finger de-spreads a relatively clean signal and this allows the overall RAKE receiver to coherently combine (with time/phase alignment) the signals to form a combined output signal that represents the addition of the multipath signals. Coherently combining the multipath signals allows the RAKE receiver to achieve an improvement in signal-to-noise ratio (SNR), essentially meaning that multipath signals can actually improve reception performance in certain types of spread spectrum systems.
Unfortunately, the characteristics of many other types of spread spectrum communications systems greatly complicate how a receiver deals with multipath signals. Some types of DSSS systems use spreading codes with poor correlation properties. The IEEE standard for high data-rate wireless LANs, known as 802.11b, is a primary example of such a system. Standard IEEE 802.11 transmissions use a single spreading code combined with binary phase-shift keying (BPSK) or quadrature phase-shift keying (QPSK) to transmit data at 1 or 2 Mbps, respectively. The 802.11b extensions provide higher data rates by defining 5.5 and 11 Mbps transmission rates. These higher data rates use a modulation format known as Complimentary Code Keying (CCK). 802.11b CCK-mode transmissions use multiple spreading codes, and the spreading codes change across symbols. While providing the ability to achieve high data transfer rates and still maintain compatibility with the standard 802.11 and 2 Mbps channelization scheme, CCK modulation does include the drawback of making it more difficult for receivers to cleanly despread individual multipath signals.
Indeed, due to the relatively poor correlation properties of the spreading codes used in 802.11b, the various multipath signals can interfere with each other and result in inter-symbol interference (ISI) at the receiver. Thus, in contrast to the CDMA digital cellular scenario, multipath signals can significantly degrade receiver performance in systems operating under 802.11b standards. Of course, multipath signals may be problematic in any type of DSSS system that uses less-than-ideal spreading codes, so the problem is not limited to wireless LAN applications. Multipath interference in DSSS systems arises from both inter-chip interference (ICI) and ISI. For the purposes of this disclosure the term ISI is understood to include both ICI and ISI. From the perspective of a DSSS receiver, each transmitted symbol results in the reception of multiple symbols arriving with relative time offsets from each other, due to the multiple signal propagation paths between receiver and transmitter. ISI, as used herein, describes multipath interference arising from these multiple received symbols and can include interference arising from multipath signal delay spreads exceeding one symbol period.
In DSSS systems where the spreading code(s) do not allow multipath signals to be individually despread without interference, RAKE receiver techniques are not applicable. The basis of RAKE receiver operation assumes that each RAKE finger can cleanly despread a selected multipath signal, which is subsequently combined with the output from other RAKE fingers to form an overall RAKE receiver output signal. If the output from the individual RAKE fingers is corrupted by multipath interference, the combined signal will be compromised and RAKE receiver performance suffers.
Channel equalization offers a potential opportunity for improving receiver performance in a multipath channel. Unfortunately, conventional channel equalization techniques are not suitable for DSSS transmissions due to complexity. For any radio frequency channel, the term “channel-coherent bandwidth” describes the portion of a given channel's available bandwidth where a relatively flat frequency response may be observed. Typically, only a small portion of a wideband DSSS channel may exhi
King Eric J.
Shan Peijun
Le Amanda T.
RF Micro Devices, Inc.
Withrow & Terranova , PLLC
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