The present invention relates to a method for retrieving ultra wideband radio transmission signals. More specifically, the invention relates to a robust low-complexity receiver scheme and method for communicating via ultra-wideband (UWB) radio transmission signals. In particular, the scheme allows for robust reception of the transmitted UWB signal even in the presence of interfering signals from concurrently transmitting devices and with packet structures having a preamble and a payload, where the signaling format of the preamble may differ from the signaling format of the payload. The invention also relates to a receiver for implementing the method of the invention.
The IEEE 802.15.4 standard (IEEE standard for information technology-telecommunications and information exchange between systems—local and metropolitan area networks—specific requirements part 15.4: Wireless medium access control (MAC) and physical layer (PHY) specifications for low-rate wireless personal area networks (WPANS),” IEEE Std 802.15.4-2006 (Revision of IEEE Std 802.15.4-2003), 2006) targets low data rate wireless networks with extensive battery life and very low complexity. Its physical layer is based on a narrowband radio, operating in the unlicensed ISM band at 2.4 GHz. IEEE 802.15.4a (IEEE P802.15.4a (amendment of IEEE std 802.15.4), part 15.4: Wireless medium access control (MAC) and physical layer (PHY) specifications for low-rate wireless personal area networks (LRWPANs),” September 2006.) is an amendment to the 802.15.4 specification. It adds an impulse-radio ultra-wide band (IR-UWB) physical layer operating in several bands of 500 MHz (and 1.5 GHz) from approximately 3 GHz to 10 GHz. This physical layer should offer a better robustness against interference and multipath propagation channels, a higher data rate and the possibility to perform ranging between devices. The IEEE 802.15.4a amendment allows for implementing either a coherent receiver or a non-coherent receiver. Due to their relatively low complexity, non-coherent receivers based on energy detection are of great interest for sensor network applications where devices should be inexpensive and have extremely low power consumption. Generally, non-coherent receivers based on energy detection are however less robust to interference than coherent receivers. It has been shown in [1] that classical energy detection receivers designed to cope with thermal noise only perform close to worst case in the presence of multi-user interference (MUI). MUI occurs due to concurrent packet transmissions. The mandatory medium access control (MAC) protocol in the IEEE 802.15.4a amendment is Aloha. With such a MAC protocol concurrent transmissions inevitably occur. MUI also occurs if several uncoordinated piconets operate in close vicinity, which is a likely scenario for devices operating in unlicensed UWB spectrum.
Scenarios like the ones described above show that there is a need for low-complexity non-coherent receivers that are able to cope not only with thermal noise and hostile channel conditions but also with the presence of MUI created by concurrently transmitting devices.
The design objectives used for the receiver of the present invention are radically different from classical design objectives for radio receivers; the receiver of the present invention is designed according to the fact that interference from other transmitters could occur, whereas classical design objectives only consider thermal noise. This directly leads to the new receiver architecture.
Nevertheless, there is still prior art and related work on impulse-radio UWB systems that is worth discussing.
Among this prior art, patent application WO 2005/074150 relates to a robust method and system for communicating via ultrawideband (UWB) radio transmission signals over multi-path channels. The system comprises an optimized non-coherent receiver structure that may lead to robust error rate performance for a wide variety of UWB multi-path channels. The non-coherent receiver is actually an energy detection receiver where a weighting function can be applied to the received signal. The duration of the integration period can also be adapted. However, the invention in this document does neither consider MUI (no form of MUI mitigation) nor burst transmissions like in the IEEE 802.15.4a standard. Furthermore, how to compute a possible weighting function or how to adapt the integration time is not mentioned.
Patent application WO 2002/032008 proposes an interference canceling technique for reducing narrowband interference in an impulse-radio UWB receiver. This technique assumes a correlator (coherent) receiver and does not apply to MUI.
The possibility of weighting the received signal is mentioned in patent application WO 2002/101942. However, no details are given on a possible weighting method in the receiver. And as in WO 2002/032008 the receiver considered is a coherent correlator receiver and burst transmissions are not envisioned.
In patent application WO 2001/076086, the use of multiple correlators to improve performance is proposed. There is no mention though of its usage for the estimation of the energy-delay profile for burst transmissions.
The inventions in patent applications WO 2007/018133, WO 2006/112850, WO 2007/011357 address issues related to synchronization and time-of-arrival (TOA) estimation of a radio signal. They are of interest since they are focused on low-complexity implementations with energy detection receivers. In WO 2007/018133, a method is proposed to robustly select a threshold for the detection of a signal in the presence of Gaussian noise. In WO 2006/112850, several methods are proposed for the analysis of a radio signal in the context of ranging and time-of-arrival estimation problems. Finally, in WO 2007/011357, one of the claims addresses the identification of the mean noise energy level and of the noise energy variance in the received radio signal. However, none of them addresses demodulation issues as our receiver does. Also, the presence of MUI is not considered.
In patent application US 2006 0093077, a method to synchronize to an impulse radio signal in a receiver based on a cross-correlation between an input signal and a template pulse train is described. The work in US 2006 0093077 is of interest as thresholding is applied on the correlation input. This has the effect of making the synchronization method more robust when MUI is present. Note that the work in US 2006 0093077 does not address demodulation issues as does the receiver of the present invention and assumes a coherent receiver architecture.
There is a large body of papers that address energy detection receivers for impulse-radio UWB systems.
The work in [7] describes a classic energy detector where the energies collected by the receiver are simply compared. Many papers recognize that it is necessary to adapt the duration of the integration window of the energy detection receiver to the characteristics of the received signal. There are several proposals of energy detection receivers where the integration time is adapted. See for examples references [8], [9], [10]. There are more sophisticated approaches described in [11], [12], [13], where the authors take advantage of partial channel state information for designing the receiver (and not only adapting the integration time), for instance, by using a weighting function. The work in [12], [13] clearly exhibits the optimality of an energy detector with a weighting function in the case the interference consists only of additive white Gaussian noise (AWGN). Examples of hardware structures to implement an energy detection receiver can be found in [6], [14]. However, none of the previous work considers MUI. Nor do they consider burst transmissions like they are used in the IEEE 802.15.4a amendment. As shown in [1], the performance degradation if MUI is not taken into account can be huge in the case such an energy detection receiver is used.
The idea of using a threshold or a non-linearity to reduce the impact of large samples from non-Gaussian interference is not new; see for instance [15], [16]. Interference created by other transmitters in impulse-radio UWB systems is not Gaussian; the probability density function of the interference exhibits an impulsive shape. As such, thresholding structures are beneficial (see [17], [18]) for the performance of impulse-radio UWB receivers. Examples of receivers using such structures can be found in [17], [18], [19], [20], [21] and the references therein. In order to be effective, the threshold must be continuously adapted, in particular, with respect to the signal-to-noise ratio of the signal of interest. This adaptation is actually far from being trivial and no solution to this particular problem is mentioned in the related work. Also, except [17] no prior art has considered the use of a thresholding mechanism with an energy detection receiver. All the related work considers coherent receiver structures. Further, additional care must be taken when the structure of the preamble is not identical to the structure of the payload.
Estimation and adaptation of the threshold to mitigate MUI, determination and estimation of weight function, as well as a solution in the case of a different signaling structure in the payload and in the preamble are elements that are addressed and solved with the present invention. Furthermore, these issues are solved with a realistic, low-complexity receiver based on energy detection.
The objects of the present invention is achieved by a method for retrieving data from Ultra wideband radio transmission signals received by a receiver and transmitted in packets containing at least a preamble known to the receiver and a payload containing data unknown to the receiver, said payload data being formed of at least one burst containing at least one pulse, said method comprising the following steps:
The objects of the present invention is also achieved by a receiver for receiving and retrieving data from Ultra wideband radio transmission signals transmitted in packets containing at least a preamble known to the receiver and a payload containing data unknown to the receiver, said payload data being formed of at least one burst containing at least one pulse, said receiver containing:
Further, the objects of the invention is achieved by a method for calculating weighting coefficients pm used for retrieving data from Ultra wideband radio transmission signals received by a receiver and transmitted in packets containing at least a preamble known to the receiver and a payload containing data unknown to the receiver, said payload data being formed of at least one burst containing at least two pulses, said method comprising the following steps :
where Lb is the number of pulses contained in one burst of the payload data; m is an integer; K is the ratio between the time separating two consecutive pulses of one burst and the sampling period; bi and bj are given by a scrambling sequence of the pulses of the payload; and ŵm−ik(1) are the weighting parameters obtained from the weighting output values.
The present invention discloses a low-complexity non-coherent receiver scheme and method for communicating via ultra-wideband (UWB) radio transmission signals. The receiver scheme disclosed here is based on the energy detection principle. However, in contrast to existing low-complexity receivers, it has a more robust performance in the presence of multi-user interference (MUI). In addition, the disclosed receiver scheme accounts for packet structures where the signaling format of the known preamble differs from the signaling format of the payload like it is e.g. the case in the new IEEE 802.15.4a standard.
The disclosed receiver scheme consists of several main components:
As described above, low-complexity, non-coherent IR-UWB receivers that are designed to only cope with thermal noise, perform highly suboptimal when they are subject to interference from other devices (multi-user interference, MUI).
As discovered by the inventors of the present application, the robustness of non-coherent IR-UWB receivers to MUI can be substantially enhanced at only a moderate increase of complexity by weighting every sample of the received signal prior to decoding according to a well-designed weighting function. The applied weighting function uses the energy-delay profile of the expected received signal. The weighting function can optionally use a thresholding mechanism to reject dominating interference terms. With the receiver structure disclosed here, both, the energy delay profile as well as the cut-off values used in the thresholding mechanism can be inferred from parameters estimated during reception of the known preamble of a packet. Further, this is possible even with packet structures where the signaling format of the preamble differs from the signaling format of the payload, as it is for example the case with IEEE 802.15.4a.
The invention disclosed here thus comprises two aspects:
These aspects are described in details below, with reference to the enclosed drawings.
The present invention and its advantages will be better understood with reference to the enclosed drawings wherein:
a shows a schematic representation of the distribution of the received signal if it consists of noise only;
b shows the distribution of the received signal if it consists of noise and interference;
At most one (possibly modulated) single pulse is sent per frame. The last part of the preamble may be composed of a special sequence (start frame delimiter, SFD) to delimit the preamble from the payload. The payload is divided into Npay frames of duration Tf and one symbol is sent per frame using a modulation format suitable for non-coherent reception (e.g. binary pulse position modulation, BPPM). The signaling format of the payload may differ from the preamble in that a symbol may be composed of a burst of Lb pulses instead of only a single pulse as it was the case in the preamble. The sender may change the polarity of each pulses composing a burst according to a scrambling sequence known to the receiver. During both preamble and payload, a time-hopping sequence known to the receiver may be used to determine the position of a pulse or burst of pulses, respectively. We assume that due to the nature of the preamble, either due to the time-hopping sequence or due to modulation according to a known preamble code (e.g. the ternary sequence in 802.15.4a), there are a certain number of chips during the preamble where the receiver can exclude that a pulse has been sent.
The received signal during the preamble then has the following format
where h(t) is the unknown received waveform, n(t) accounts for thermal noise and MUI and si is given by a known preamble code (e.g. siε{−1, 0, +1} in the case of the IEEE 802.15.4a ternary sequence). For simplicity, we here assume regularly spaced pulses and no time-hopping during the preamble.
The received signal comprising the payload has the following format assuming BPPM
where ai ε{0, 1} is the ith symbol of the payload which is unknown, ci denotes the time-hopping sequence and bij ε±1 is given by the scrambling sequence. To ease notation but without loss of generality we consider only the first symbol (i.e. we set i=0 and drop the index i) and we assume c0=0
To the best of our knowledge, existing designs further neglect the impact of MUI and assume that n(t) is purely additive white Gaussian noise (AWGN) with power spectral density N0/2.
To decide on the sent symbol a0, some existing architectures simply compare the energy received in the first half of the frame to the energy received in the second half. If the energy received during the first half is bigger than the energy received in the second half they decide on a0=0 and vice versa. Optionally the integration time may be adjusted to prevent the integration of too much noise. These designs have obvious drawbacks when MUI is present in the half of the frame where the sent signal was not present and performance is accordingly poor in these cases.
The decision is then taken according to
It can be shown that an energy detection receiver employing above decision rule is close to optimum according to the maximum-likelihood (ML) criterion if n(t) is assumed AWGN and Lb=1, i.e. there are no bursts in the payload.
Assuming that perfect synchronization has been obtained between sender and receiver, the weighting output value obtained during the ith pulse of the preamble can be written as
ym,ipre=si2∫(iN+m)T(iN+m+1)Th2(t−iNT)dt+∫(iN+m)T(iN+m+1)Th2(t−iNT)dt+2si∫(iN+m)T(iN+m+1)Th(t−iNT)n(t−iNT)dt (7)
where m=0, . . . , N−1. Assuming n(t) AWGN with zero mean and taking expected values, an estimate ŵm of wm (herein called weighting parameters) can be obtained from the preamble as
where M1 and M0 are the number of terms in the first and second summation, respectively. The second summation is obtained by summing over all samples where the received signal is not present and {circumflex over (n)} is thus an estimate of the noise energy contained in a window of duration T.
where the weighting coefficients or weights pm are found according to
where K=Tc/T and w(l) m, l=1, . . . , Lb−1 is given by
wm(l)=∫mT(m+1)Th(t)h(t−l·Tc)dt (11)
Only wm(0)=wm can be estimated by the existing energy detection receivers given above. Equation (10) thus not only defines a new weighting function but also leads to a new receiver structure allowing to estimate the quantities of the weighting parameter wm(l). This new receiver structure is described in details below.
where FNC
is the power spectral density of the thermal noise, B is the bandwidth of the received signal, given by the band limiting filter, PFA is a small false-alarm probability defining the threshold (alternatively νm can be seen as the (1−PFA)-quantile of a non-central chi-square distribution) and λm is given by
The threshold can be made adaptive by adjusting PFA according to feedback from the physical layer. Increasing PFA leads to a lower threshold and vice versa.
As can be seen from (12) and (13), the threshold value νm depends on the weighting coefficients pm as well as on the thermal noise level. Both quantities have to be estimated during the preamble phase. The receiver then applies a non-linear threshold operation governed by the threshold νm to the received samples prior to the decision process to mitigate or even reject high interference terms. Thinkable non-linear operations are for example to null samples above the threshold
ympay=ympay∀m:ympay≦νm
ympay=0∀m:ympay>νm (14)
to limit samples above the threshold to the threshold
ympay=ympay∀m:ympay≦νm
ympay=νm∀m:ympay>νm (15)
or to set samples above the threshold to the value of the estimated energy-delay profile
ympay=ympay∀m:ympay≦νm
ympay=pm∀m:ympay>νm (16)
Other non-linear operations based on the threshold value νm are of course possible, the simple and common choices given here just serve for illustration.
From the quantities Ŵm(l) , lε{0, . . . , Lb−1} an estimate of the weights or weighting coefficients {circumflex over (p)}m can be directly calculated using (10) under the condition that K=Tc/T is an integer greater than or equal to one or in other words T≦Tc. In this case the receiver with the structure given in
If however K−1 is an integer greater than one, i.e. if a larger integration time and lower sampling frequency is desired, a maximum of Lb−1−l additional integrators parallel to the single one depicted in
Note that in either case, K≦1 and K<1, the additional complexity with respect to a classical energy detection receiver is only needed during the estimation of the energy delay profile. During the other phases of packet reception, synchronization and decoding, the additional circuitry is not used. This also limits the additional memory requirements of this more sophisticated receiver.
In addition to the weights pm or weighting coefficients, we also have to estimate the noise power spectral density N0/2 which is used to calculate the threshold value νm. An estimate can be obtained from {circumflex over (n)} given in (8) as
The estimation of ŵm(0) can be further made more robust to MUI by not considering all available samples ym,ipre when averaging according to (8). From (11) it can be seen that due to the squaring operation in the receiver, interference can only be additive for the term wm(0). Therefore, terms in the received signal suffering from MUI are likely to have a larger energy than terms that do not suffer from MUI. Based on this observation, (8) can optionally be replaced by
where only samples below a threshold ympre,α are taken into account in the first summation. ympre,α is the α%-quantile of the observation ym,ipre (meaning that α% of the observed samples lie below the value ympre,α). α is a design parameter that can be adjusted based on the expected interference level. ympre,α can be estimated from the received ym,ipre by e.g. storing a set of samples and taking the sample α%-quantile over the stored set. The number of terms M1 in the first summation would then be fewer with respect to (8) but typically include those that suffer less from the effect of MUI.
Note that other similar thresholding schemes based on α%-quantiles are also thinkable, e.g.
where
and
The remaining question is how to determine the threshold {circumflex over (q)}β. Because we do not know the noise variance, we cannot calculate qβ analytically and set {circumflex over (q)}β=qβ. However, we know that the shape of the “noise-only” distribution is chi-square so we can calculate the fraction
which is independent of the noise variance and only depends on the number of degrees of freedom of the distribution which we know. Further, we can easily determine the sample median of our observation {circumflex over (q)}50 (It is usually robust to outliers and thus quite close to q50). We can thus find the threshold as
{circumflex over (q)}β=φ·{circumflex over (q)}50 (24)
It can be seen from
It can be seen from
The method and the receiver of the present invention directly apply to IEEE 802.15.4a receivers and by extension to the IEEE 802.15.4 standard also known as ZigBee.
With the proliferation of wireless networks, not only as Ethernet cable replacements but also for sensor networks, enabling environmental control, home automation, medical applications, industrial and building automation, . . . interference between devices will increase. Interference can come from similar devices, the so-called in-system interference (for instance, two networks operating in the same area), or from external devices (for instance, created by a narrowband interferer). Our invention greatly reduces the impact of in-system interference.
As such, as the number of deployed networks increase, the performance of these networks and those already installed will be affected by the increase of interference. Solutions to combat interference and to reduce its impact will be required. Our invention addresses this issue at a very moderate complexity increase. Indeed, for the analog front-end of our receiver, the supplementary filters and analog-to-digital converters are only required during the channel estimation phase. This amounts to roughly 5% of the total duration of the reception of a packet. The trade-off between the increase of power consumption and the reduction of packet loss due to interference clearly justifies this small increase in receiver complexity and the small impact on the power consumption.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB2009/050468 | 2/5/2009 | WO | 00 | 7/30/2010 |
Publishing Document | Publishing Date | Country | Kind |
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WO2009/098652 | 8/13/2009 | WO | A |
Number | Name | Date | Kind |
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3069654 | Hough | Dec 1962 | A |
6335949 | Kim | Jan 2002 | B1 |
7327794 | Fanson et al. | Feb 2008 | B2 |
7613257 | El Fawal et al. | Nov 2009 | B2 |
8140017 | Shi et al. | Mar 2012 | B2 |
20040120409 | Yasotharan et al. | Jun 2004 | A1 |
20050254604 | MacMullan et al. | Nov 2005 | A1 |
20060093077 | El Fawal et al. | May 2006 | A1 |
20060158358 | Seo et al. | Jul 2006 | A1 |
20070127600 | Sato et al. | Jun 2007 | A1 |
20080069260 | Wellig | Mar 2008 | A1 |
20090075590 | Sahinoglu et al. | Mar 2009 | A1 |
Number | Date | Country |
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1 917 357 | May 1970 | DE |
WO 0176086 | Oct 2001 | WO |
WO 0232008 | Apr 2002 | WO |
WO 02101942 | Dec 2002 | WO |
WO 2005074150 | Aug 2005 | WO |
WO 2006112846 | Oct 2006 | WO |
WO 2006112850 | Oct 2006 | WO |
WO 2007011357 | Jan 2007 | WO |
WO 2007018133 | Feb 2007 | WO |
WO 2009098652 | Aug 2009 | WO |
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