A NEW SIGNAL DETECTION METHOD FOR TR-UWB
By Time Delayed Sampling & Correlation (TDSC)
Muriel Muller, Yang Ni, Roger Lamberti, Charbel Saber
GET-Institut National des Télécommunications
9, rue Charles Fourier, 91011 Evry France,
Keywords: Ultra-Wideband (UWB) communications, Transmitted Reference (TR) UWB, non-coherent detection.
Abstract: This paper introduces a new signal detection method for Low cost, Low power and Low complexity (L3)
TR-UWB systems for medium to low data rate applications such as sensors networks. This new detection
method is based on a time_to_space conversion realizable by an analog waveform sampler. This method
overcomes the major difficulties in a traditional TR-UWB detection methods based on wide band delay
lines. Finally the relaxed timing precision needed in symbol synchronization contributes further to lower the
system power consumption. This concept has been validated by simulation with real data from experimental
setup. The results will be presented and compared also with other solutions.
1 INTRODUCTION
Many applications (Metha, 2004), (Oppermann,
2004), (Duo, 2004) require low cost, low power and
low complexity (L3) short range wireless
communications means. Most of the current wireless
communications systems are designed for the data
transmission in a computer related context and do
not satisfy completely these criteria. Our motivation
in this research activity is to design wireless
communications devices with L3 characteristics
based on Impulse Radio (IR) UWB concept. The
apparent hardware simplicity of an UWB system,
hides a lot of design challenges (Bettayed, 2003).
The high switching speed for the short duration
UWB signal generation and the high timing
resolution for UWB signal detection and
synchronization between transmission and reception
generate a considerable extra hardware complexity
associated with very important power consumption
overhead.
In an impulse radio based UWB system, the pulse
generation can be implemented by using fast
switching devices such step recovery diode (SRD)
with a reasonable power consumption and
complexity. This is not the case for UWB pulse
detection.
Two main UWB detection methods can be
distinguished.
The coherent detection method, based on a signal
correlation between the incoming UWB signal and a
local generated template (Time Domain, 2001),
(Mielczarek, 2003), is requiring channel estimation.
The other one is based on non-coherent energy
detection method (Doré,2005), (Stoica, 2005).
Theoretically speaking the coherent method gives
better detection result than that of the non-coherent
one.
But in reality, the high precision synchronization
and local template generation in a multi-path
environment are extremely difficult to be
implemented with simple hardware.
Many UWB receivers use some number of analog
correlators to collect the signal energy in front-end
rake receiver architecture. The need to capture a
large amount of the transmitted energy involves to
use a great number of paths, besides the propagation
which deforms the pulses shape, path to path, leads
to a very high complexity both on hardware and
software (estimation channel) (Durisi, 2004).
Some non-coherent detection based simple systems
use signal energy detection which consists of
measuring the energy in the incoming signal. The
detection efficiency of this method is conditioned by
the degree of the temporal energy concentration of
19
Muller M., Ni Y., Lamberti R. and Saber C. (2006).
A NEW SIGNAL DETECTION METHOD FOR TR-UWB - By Time Delayed Sampling & Correlation (TDSC).
In Proceedings of the International Conference on Wireless Information Networks and Systems, pages 19-25
Copyright
c
SciTePress
an UWB signal. This detection method is usually
implemented by using fast switching devices such as
Schottky diodes or tunnel-effect diodes.
In spite of obvious hardware simplicity, this type of
methods presents several limitations. The necessary
low-pass post-filtering decreases considerably the
amplitude of the signal at the output of the detector,
spreads out this same signal over the axis of time.
This leads to a much lower temporal discrimination
power than that of initial UWB impulses and results
in an unacceptably low sensitivity. Fig. 1 gives the
comparison between the instant signal power and the
low pass filtered signal. We can observe an
important loss of signal amplitude due to the energy
dilution in time.
Figure 1: Energy detection systems.
From these observations, we think that the
Transmitted-Reference (TR) UWB architecture
(Rushforth, 1964), (Hoctor, 2002) could be a
solution to our L3 UWB systems for several reasons.
Firstly in TR-UWB system, each transmitted signal
pulse is preceded or followed by a reference pulse.
Due to the short time duration between these pulses,
the propagation channel can be considered as
constant and the two pulses will keep a strong
correlation at the reception point even in a strong
multi-path environment. So the TR-UWB signal can
be detected by using a pseudo coherent scheme
where the TR-UWB signal is correlated with a time
delayed copy of this signal as shown in Fig. 2.
Secondly the time delay between the signal pulse
and the reference pulse can be seen as a parameter of
signal diversification for channel coding and
multiplexing. Besides TR-UWB can be as efficient
as Rake-receiver for energy collection (Zasowski,
2004), but with a much simpler hardware.
Despite the advantages of TR-UWB, the major
difficulty in the realization is the broadband delay
line with wide bandwidth, highly linear phase,
perfect impedance adaptation and highly stable
delay (Goeckel, 2005). An implementation using
transmission line presents several problems,
especially the delay precision and stability. The lack
of real-time programmability is another limitation in
a real exploitation of TR-UWB. Moreover, a real
transmission line presenting an exploitable delay
value remains impossible to integrate in a miniature
circuit simply because of its physical dimension.
Figure 2 : Simplified TR-UWB communication system.
In this article we proposed a very different approach
based on a time-space conversion using an analog
sampler. The TR-UWB signal is sampled by two
analog waveform samplers with pre-defined delay
which matches the time delay between the pulses in
a TR-UWB frame. The signal detection will be done
by applying a waveform correlation between the two
TR-UWB signal samples. We called this new
concept for UWB data transmission, the Time
Delayed Sampling and Correlation (TDSC) which
will be detailed in section II. In section III, we will
report the first experimental validation results made
in different propagation conditions. These results
demonstrate the potential advantages of this TDSC
concept in L3 UWB communications systems.
Finally in section IV, we will give some conclusions
and perspectives in this research works.
2 TDSC - A NEW APPROACH
FOR TR-UWB SIGNAL
DETECTION
Recently, other fields such as the physics of high
energy particles use high speed waveform samplers
in order to capture and record highly impulsive
signals from different detectors. These signals have
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20
the similar temporal and electrical properties as
those of UWB. The most significant work is done by
(Kleinfelder, 2003) in CMOS technology. The
realized circuit can capture several hundred points of
a signal at 10 GHz sampling rate.
Our proposed TDSC detection scheme is highly
inspired from this work. The analog waveform
sampler as shown in Fig. 4 uses an asynchronous
delay line composed of simple inverters to generate
the sampling commands at the different moments.
This asynchronous implementation permits a
sampling rate much higher with much lower power
consumption than that of a synchronous design by
using a global and explicit clock.
By using two waveform samplers as shown in Fig. 3,
one is activated at the instant T and the other at
T+D, two time delayed and sampled waveforms of a
TR-UWB signal can be obtained. If a TR-UWB
signal pulses fall in these sampling windows, we
will have two similar waveforms because the double
pulses in a TR-UWB frame have the same waveform
distortion after the propagation in a time invariant
channel as explained in section I. The absence of
TR-UWB signal will result in two totally
independent waveforms from the samplers. By
consequent, the TR-UWB signal detection here can
be easily done by using a simple correlation
operation between the time delayed sampled
waveforms. This principle is called Time Delayed
Sampling and Correlation. Fig. 5 gives a graphical
representation of this detection concept.
By using this method, we can see that the TR-UWB
will be sampled twice with a constant time delay.
The role of the broadband delay line is replaced by a
time delayed double sampling which removes
completely the need of an explicit analog signal
delay line and all the design difficulties associated
with. In this case, the delay is only applied to the
sampler’s command digital signals, which can be
generated easily and programmably in real-time
from the system clock with an extremely high
precision and high stability. So the parameter D in
TR-UWB can be used for channel coding and
multiplexing. Fig. 3 gives the overall structure of
TDSC (Ni, 2005).
Figure 3 : General scheme of Time Delayed Sample &
Correlation system, based on two samplers temporally
delayed.
Figure 4 : The principle of an asynchronous delay line
based analog waveform sampler.
The TDSC detection cannot be done continuously in
time. So a synchronisation between the TDSC
operation and the incoming TR-UWB signal is
needed. But in contrast to other detection methods
(Time Domain, 2001), TDSC method imposes much
lower constraint on the precision of this
synchronisation. As shown in Fig. 5, when the UWB
pulses fall inside the sampling windows, it can be
detected reliably.
This means that the timing precision for this
synchronisation is indexed at the TR-UWB frame
duration which is much larger than that for pulse
detection.
Input
signal
τ
τ
τ τ
T
Acquisition
V
1
V
2
V
n
SamplerA
SamplerB
ArrayCorrelator
D
TR‐UWB
Signal
Output
signal
Acquisition
signal
….
….
A NEW SIGNAL DETECTION METHOD FOR TR-UWB - By Time Delayed Sampling & Correlation (TDSC)
21
Figure 5: Principle of TDSC method. a) Waveforms of the
time delayed sampled TR-UWB signals captured by the
samplers A and B. b) The detection of impulse doublet is
obtained with a simple correlation operation of the two
delayed sampled waveforms.
This low timing precision necessary in detection
synchronisation reduces not only considerably the
signal acquisition time but also the complexity of
synchronisation tracking. This characteristic is
particularly interesting for sensor networks like
applications where the data transmission is sporadic
with very low duty cycle. The fast acquisition and
tracking can reduce significantly the system power
consumption by reducing the activation time which
is often conditioned by acquisition time for small
data packages.
3 EXPERIMENTAL VALIDATION
TDSC detection method has been validated by using
simulation on the data captured from an
experimental setup. This experimental setup gives
realistic input signals for the TDSC simulation
program in order to be as close as possible to the real
TR-UWB working conditions. The results of the
validation give some design guide to further VLSI
implementation.
3.1 Experimentation Setup
The experimentation setup is shown in Fig. 6. We
used a off the shelf pulse generator in order to
generate a rectangular pulses train as shown in Fig.
7. The symmetric rising and falling edge transition
time is less than 5ns (Pulse Generator E-H research
laboratories model 137A), and we set the rectangular
pulse width to 100 ns.
A simple thick monopole antenna has been used for
this experimentation. The inevitable ringing in this
kind of antenna permits to test the tolerance of
TDSC detection method vis-à-vis to the impedance
adaptation problems in real implementation.
Monopole antennas will reshape the digital pulses
into wide band limited pulses. So the rising and
falling edges of each digital pulse will generate an
impulse doublet with opposite polarities and a
temporal delay D corresponding to the digital pulse
width. Then, the impulse doublets are sent,
propagated in an indoor environment and received
by a digital oscilloscope with memory of 300MHz
bandwidth. An example of the captured TR-UWB
signal is shown in Fig. 8. Finally, we use the Matlab
software to simulate the TDSC detection method on
these sampled TR-UWB signals.
Figure 6: Experimentation setup: A off the shelf pulse
generator, two monopole antennas and a digital
oscilloscope as sampler, were used.
Figure 7: Rectangular input signal. The temporal delay D
between the two pulses of the doublet is around 100ns.
Two doublets will be separated by 300ns. A silence space
between two couple of doublets is equal to 500ns.
0
2
4
0,E+00 5,E-07 1,E-06 2,E-06 2,E-06 3,E-06
Time (second)
Sampler A
Sampler B
Delay D between A & B
Correlation between A & B
Waveforms of the Time Delayed Sampled TR-UWB signal
Signal detection by the Correlation between the Time Delayed
Sam
p
les
Detection of
impulse doublet
a)
b)
TTL/ CMOS
pulse
Mono
p
ole
Digital
Oscilloscope
Mono
p
ole
D
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Figure 8: Real output doublets sampled and recorded
thanks to a digital oscilloscope. The reference pulse and
the data pulse are separated by a temporal delay D.
3.2 Experimentation Results
In the TDSC principle, the TR-UWB signal
detection is done by correlating two temporally
delayed sampled TR-UWB signal. This is simulated
by applying cross-correlation function to two
temporal windows on the recorded TR-UWB signal.
These temporal windows correspond to the double
time delayed waveform samplers. In order to skip at
first the problem of synchronisation, these windows
will slide on the recorded TR-UWB signal in a
contiguous way, as shown in Fig. 9-a. In the same
figure (Fig. 9-b), the result of the simulated TDSC
detection method with a TR-UWB signal sampled at
5Ghz rate (200ps). It is demonstrated that the basic
cross correlation function gives a satisfied results
and the virtually null output during TR-UWB signal
absence makes the decision threshold setting very
easy.
In order to evaluate the performance of TDSC
method, different configurations and parameters
have been tested.
Figure 9: a) Principle of the algorithm used to validate the
TDSC concept. One sampling window is sliding on
another window about a fixed temporal delay equal to D.
b) Correlation result between the two sampled signals.
Here the sampling rate was equal to 0,2ns.
In the above example, the receiving antenna was
placed 250 cm away from the transmitting antenna
with the same height.
Many others measurements were carried out where
the distance varied from 80 cm to 5 meters, with
constant emission power. The sampling rate also
varied from 200ps to 2ns. For all these cases, the
TDSC method gave very good detection
performance. Note that above a 2ns sampling rate,
the TDSC detection failed. This is consistent with
Shannon theorem.
These results are very promising for the TDSC
concept and the future realization circuits. Based on
these promising results we decided to investigate
others properties of TDSC method.
3.2.1 Synchronisation Tolerance and
Temporal Discrimination
The high speed impulses used in IR-UWB need a
high precision temporal synchronisation between the
transmitter and the receiver. In a classic IR-UWB
system, this temporal synchronisation precision
should be higher than the minimum pulse width.
This requirement represents one of the major
challenges in a real hardware implementation.
In the TDSC method, the detection can be effective
when the impulse doublet falls inside the temporal
sampling windows. This means that the temporal
synchronisation precision is indexed to the symbol
rate but not that of individual impulses. The
maximum width of the sampling window is to the
delay D and this gives a large synchronisation
facility and tolerance.
But another interesting point here is that this large
synchronisation tolerance has no impact on the
temporal discrimination power of the TDSC
detection because the temporal discrimination power
of the TDSC method is conditioned by the cross-
correlation function applied onto the sampled
signals. This high temporal discrimination capability
is illustrated by the following aspect: - the separation
between two pulses inside a TR-UWB doublet.
In order to code one data bit, two pulses are
transmitted, separated by a known delay D. This
delay can be seen as selectivity parameter (similar to
frequency in a frequency division system) at the
reception. A high selectivity based on this parameter
can not only reduce noise but also give higher
channel capacity for coding and multi-access.
a)
b)
A NEW SIGNAL DETECTION METHOD FOR TR-UWB - By Time Delayed Sampling & Correlation (TDSC)
23
In order to validate this selectivity, we carried out
simulations by varying the delay D at TDSC
detection stage for a recorded TR-UWB signal with
D=127ns at transmission here. We varied the value
of D +/-10 sampling points around its nominal value.
The simulation result is shown in Fig. 10. Here the
sampling period is 200ps, the temporal
discrimination can be evaluated at +/-2ns.
This characteristic can not be found in other
detection methods. For example, an energy detector
integrates all incoming energies and results in a low
temporal discrimination. Besides some information
on the incoming signal can be lost such as pulse
polarity. The coherent detection method gives a
theoretically better performance but the difficulties
in the local template generation and ultra-high
precision synchronisation make it impractical in
simple low cost and low power systems.
(a)
(b)
Figure 10: a) TDSC results for small variations around the
value of delay D. b) The variation of the maximum
detection versus D.
3.2.2 Detection and MP Energy Collection
under LOS & NLOS Contexts
We conducted experiments with and without a line
of sight propagation path in order to evaluate the
performance of TDSC detection in the two cases.
For the first case (Fig. 11), the two monopole
antennas are in line-of-sight, at a distance of about
2,50 meters. The second case (Fig. 12), is performed
with a metallic obstacle between the two monopole
antennas, in order to obtain a non line-of-sight
scheme.
In a multi-path (NLOS) context, the received TR-
UWB impulse doublets can be strongly confused
together as shown by the upper waveform in Fig. 12.
When the TDSC method is applied to this signal, the
successive TR-UWB doublet can be clearly
separated and detected, despite the energy spreading
as shown in the lower waveform in Fig. 12.
Figure 11: Simulation result for LOS experiment.
Figure 12: Simulation result for NLOS experiment.
4 CONCLUSION &
PERSPECTIVES
In this paper, we have introduced a new TR-UWB
signal detection concept -The Time Delayed
Sampled and Correlation (TDSC). This method has
been presented in details and validated
experimentally. This detection method gives
numerous advantages such as large synchronisation
tolerance, high multipath signal energy collection
efficiency in strong multi-path environment, high
signal selectivity and modular CMOS friendly
design with low power consumption, etc. Actually
this validation has been done in 300MHz band, a
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CMOS waveform sampler circuit capable to operate
at 10GHz is on the way and this circuit will permit a
full validation at the lower end of FCC UWB band.
In parallel, the theoretical investigations on this
method by using different channel models proposed
by IEEE P802.15-WPANs (Foerster, 2003),
(Molisch, 2003) are on the way.
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