Impulsive Noise Characterization of InVehicle Power Line

IEEE TRANSACTIONS ON ELECTROMAGNETIC COMPATIBILITY, VOL 50, NO 4, NOVEMBER 2008 861 Impulsive Noise Characterization of In Vehicle Power Line Virginie Degardin, Martine Lienard, Pierre Degauque, Member, IEEE, Eric Simon, and Pierre Laly Abstract—Impulsive noise can have a great influence on the per formance of in vehicle power line communication systems Inten sive noise measurements in the time domain were thus carried out on five different vehicles Preliminary trials were first made on a statio.

Impulsive Noise Characterization of

In-Vehicle Power Line

Virginie Degardin, Martine Lienard, Pierre Degauque, Member, IEEE, Eric Simon, and Pierre Laly

Abstract—Impulsive noise can have a great influence on the

per-formance of in-vehicle power line communication systems

Inten-sive noise measurements in the time domain were thus carried out

on five different vehicles Preliminary trials were first made on a

stationary vehicle and the motor idling, but the characteristics of

the measured low-amplitude pulses greatly vary from one car to

another We thus emphasize the characteristics of high-amplitude

pulses, greater than 70 mV, observed when the vehicles were

mov-ing in traffic, durmov-ing a 20-min trip Noise is statistically

character-ized in terms of duration, frequency content, peak amplitude, and

time interval between successive pulses Stochastic models based

on mathematical distribution functions and fitting the

experimen-tal distribution of the various pulse characteristics are proposed It

has been found that interarrival time, i.e., the time interval between

two successive pulses, is rather short and would be thus the most

critical parameter when optimizing the power line communication

physical layer.

Index Terms—Impulsive noise, in-vehicle power line

communi-cation, wire communication.

I INTRODUCTION

OVER the last few decades, electronic systems have been

used more and more in vehicles to insure the safety and

comfort of the occupants These include both safety systems,

such as antilock brake system (ABS), electronic stability

pro-gram (ESP), and electromechanical brake-by-wire (EMB), and

comfort systems, such as adaptive cruise control (ACC), as well

as numerous multimedia systems providing automotive

multi-media and personal computer networking

In most cases, automobile manufacturers have chosen to

transmit data from sensors to computers via dedicated

com-munications networks, using standardized protocols like

con-troller area network (CAN), local interconnect network (LIN),

media-oriented systems transport (MOST), or FLEXRAY

Cur-rently, twisted wires or fiber optics cables are used for

transmit-ting safety-related signals This practice has led to increasingly

complex network architectures, with the result of increasing the

weight of the cable harness and the number of connections,

making it harder to insure the reliability of the combined

sys-tems One possible medium-term solution is to use the dc power

Manuscript received January 3, 2008; revised June 30, 2008 Current version

published November 20, 2008 This work was supported in part by the French

Ministry of Research, by the Region Nord Pas de Calais, and by the FEDER

funds, conducted in collaboration with PSA Peugeot Citroen, Valeo, and Institut

National des Sciences Appliquees de Rennes (INSA-Rennes).

The authors are with the Institute of Electronics, Microelectronics and

Nan-otechnology (IEMN)/Telecommunications, Interference and Electromagnetic

Compatibility (TELICE), University of Lille, 59655 Villeneuve d’Ascq, France

(e-mail: virginie.degardin@univ-lille1.fr; martine.lienard@univ-lille1.fr;

pierre.degauque@univ-lille1.fr; eric.simon@univ-lille1.fr;

pierre.laly@univ-lille1.fr).

Digital Object Identifier 10.1109/TEMC.2008.2006851

network as the physical support for transmission [1]–[6] This method, often called power line communication, is currently being developed primarily for use in indoor applications to al-low, for example, an Internet connection via any home electrical outlet

The principal difficulties encountered when developing such power line carrier (PLC) systems are mostly related to the chan-nel transfer function, which is highly variable both in terms of frequency and time [7], and to the impulsive noise generated

by the various electrical devices connected to the network In fact, unlike transmissions over coaxial and/or twisted lines, the disturbing currents and voltages that propagate through a power network are superposed directly over the useful signal Knowl-edge of the noise characteristics is thus essential for optimizing modulation schemes and channel coding (e.g., error-correcting codes, interleaving, and equalization algorithms), and also for predicting link performance

In the automobile domain, electromagnetic compatibility (EMC) standards have already been established, but they are defined either by car manufacturers for each individual piece

of equipment or by international normalization bodies that im-pose a maximum level for the electromagnetic field radiated

by a vehicle at a given distance The measurement proce-dures are, of course, clearly explained in these standards, but these procedures are primarily defined in the frequency domain This can be problematic for studying digital telecommunication performance

In the time domain, only a few studies have been published For example, the process for characterizing transient voltages for automotive 42-V power systems is described in [8], with an emphasis on the effects of the relay arcing process, used mainly

to deal with EMC problems A few measurements of channel transfer functions and a description of several noise pulses are provided in [9], together with a model of the interarrival time (IAT) distribution In an attempt to overcome this lack of data

in the literature, we present in this paper an exhaustive study of impulsive noise, exploring a frequency bandwidth ranging from

500 kHz to 40 MHz, which corresponds to a possible bandwidth for future automotive PLC systems [3], [5], [10], [11] It must

be emphasized that we do not seek to identify and characterize each disturbing source Preliminary measurements on one car,

of the channel transfer function and the impulsive noise at one point, are described in [12], while in [13], four measurement points in the same car were considered

To make a statistical approach of the impulsive noise charac-teristics, these previous studies have been extended by making extensive noise measurements, taken at various connection points in five new upmarket cars First, Section II presents the 0018-9375/$25.00 © 2008 IEEE

tions and by using a small triggering threshold for the acquisition

system, and in a car in driving condition using a threshold higher

than the peak amplitude of the pulses already recorded Few

results are given in Section III for stationary conditions

show-ing that pulses are mainly due to interference sources rather

than noise randomly generated by electronic equipment

Fur-thermore, the pulse characteristics are often quite different from

one car to another Additional measurements on a larger number

of cars would thus be needed to have an idea of the spread of

the pulse characteristics We thus focus our attention to pulses

recorded in driving conditions, under the constraint on high

trig-gering threshold Section IV describes the results of the analysis

of the distribution of the peak amplitude, pseudofrequency,

dura-tion, and IAT of the pulses Probability density functions fitting

the experimental data are also proposed We conclude this paper

by a short comparison between in-house and in-vehicle noise

characteristics, since actual PLC modems have been primarily

optimized for in-house communications

II IMPULSIVENOISEMEASUREMENTSYSTEM

Before describing the measurement techniques and how the

impulsive noise was extracted from the ambient noise and

char-acterized statistically, it is important to briefly review the main

features of PLC communication systems in order to highlight

the importance of characterizing noise in the time domain as

well as in the frequency domain

A Main Features of PLC Communication Systems

The cable harness tree-shaped bundle configuration is

com-posed of numerous interconnected multiconductor transmission

lines During data transmission, reflections occur at the different

junctions and on the unmatched terminal equipment Orthogonal

frequency division multiplexing (OFDM) is usually chosen to

cope with the effects of such multipath propagation, though code

division multiple access (CDMA) has also been studied [14]

To give some figures for a very simple example, a usual

HomePlug 1.0 scheme for a bit rate of 14 Mb/s is based on a

maximum OFDM symbol (21 B) duration of 8.4 µs [15] Each

maximum code word consists of 20 symbols, plus additional

bytes associated with a Reed–Solomon (RS) and convolutional

concatenated code The duration of a PHY block of 20 symbols

is 168 µs Depending on the characteristics of the impulsive

noise, such as pulsewidth and pulse spacing, and thus on the

number of pulses occurring during a code word, the RS code may

or may not be able to correct the errors Interleaving the code

words is thus often used, but to optimize the interleaving depth,

Fig 1 Typical noise recording compared to an OFDM signal with a PSD of –60 dBm/Hz.

the statistical properties of the impulsive noise and especially the IAT must also be known

Another important parameter that plays a leading role in com-munication performance is, of course, the power level of the injected signal Fig 1 superposes the impulsive noise measured

in a vehicle (method to be explained later) with an OFDM signal with a power spectral density (PSD) of –60 dBm/Hz This PSD value seems to be the value that will most likely be authorized by international normalization bodies for indoor PLC applications

As shown in Fig 1, the signal and peak values of the dis-turbing pulses have the same order of magnitude, equal to about

500 mV It must be emphasized that, due to EMC constraints, one cannot arbitrarily increase the transmitting power The EMC specifications can be defined by the car manufacturer as well as

by international standards For example, International Special Committee on Radio Interference (CISPR) 25 (electromagnetic disturbances related to the electric/electronic equipment in ve-hicles) [16] specifies that to obtain acceptable radio reception

in a vehicle using typical radio receivers, the disturbing voltage

at the end of the antenna cable should not exceed a limit on the order of 6 dB·µV The choice of the maximum PSD is out

of the scope of this paper, but this example underlines that an in-depth knowledge of impulsive noise statistics is necessary for studying PLC communication performance

B Measurement Setup

A test platform [see Fig 2(a)] was developed to measure the impulsive noise in both stationary vehicles and vehicles moving

in traffic As illustrated in Fig 2(b), the disturbing voltage be-tween the power line and the ground (the coachwork or a ground wire) was measured through a capacitive coupling composed

of a high-pass filter with a cutoff frequency of 500 kHz and an

impedance matching RC network It is followed by a transformer

to isolate the output signal from the power supply and by a pro-tecting device, limiting the peak amplitude to 3.5 V The total insertion loss of these devices is 7 dB The signal is then ampli-fied and low-pass filtered, and the cutoff frequency of the filter being 40 MHz The main characteristics of the coupler are total power gain: 6.5 dB, gain flatness: 1 dB, bandwidth: 0.5–40 MHz,

Fig 2 (a) Measurement setup (b) Block diagram of the coupling device.

input voltage standing wave ratio (VSWR) maximum in the 1 dB

bandwidth: 1.5, and output VSWR maximum: 1.2

One of the problems in measuring impulsive noise is

dis-tinguishing this kind of noise from the background noise For

wireless communications, a procedure proposed in [17] was to

capture data in both horizontal and vertical polarization

simul-taneously Unfortunately, in our application, the only possibility

is to adjust a threshold level A spectrum analyzer was thus used

to measure this background noise In the frequency band from

500 kHz to 2 MHz, the noise spectral density was shown to

decrease with frequency from –110 to –130 dBm/Hz, and then

to remain constant between 2 and 40 MHz Given the 40-MHz

bandwidth of the acquisition system, a triggering threshold

vary-ing between few millivolts and 200 mV was chosen, dependvary-ing

on the configuration of the measurements, as it will be explained

in Sections III and IV

The acquisition time (i.e., the width of the observation

win-dow) after triggering was 650 µs, the signal being sampled at

a frequency of 100 MHz before it is stored At the end of an

observation window, a clock with a time resolution of 400 ns

was activated to measure the time intervals separating two

suc-cessive recordings in order to determine the IAT between two

successive pulses, even if the pulses are not in the same

obser-vation window [see Fig 2(a)] The minimum time between two

successive recordings, i.e., before the acquisition system can be

triggered again, is 250 ns and is thus negligible compared to the

average time between two successive pulses

C Detection of the Impulsive Noise and Examples of

Recorded Pulses

Data processing was necessary to extract the different pulses

occurring during an observation window, in order to analyze

their properties in both the time and frequency domains To

avoid ambiguities due to the presence of background noise,

a technique based on probabilistic criterion and using a

deci-sion level is described in [18] Once the decideci-sion level is fixed,

the pulse start and end points are determined where the

mea-sured signal crosses the decision level with positive and negative

slopes, respectively However, applying such a technique to

ex-tract pulses having the shape of a damped sinusoid, as we will

see in a next paragraph, seems quite difficult We have thus

pre-ferred to develop another approach, consisting of calculating the

cumulative variance y(k) of the sampled signal during the time

k∆t (denoted hereafter as k), ∆t being the sampling period If

Fig 3 (a) Example of a noise recording (b) Cumulative variance during an observation window.

x i is the signal amplitude sampled at the instant i, y(k) is the

result of

y (k) =

k−1

i= 0



(x i)2−

 1

n

n −1

i= 0

x i

2

where n is the total number of samples during an observation

window

In the presence of background noise, the cumulative variance

is a linear function of k, and thus a break in the line indicates

the presence of a pulse The duration of a pulse or a burst

corresponds to the time interval during which the slope of y(k)

is significantly different than the slope of background noise only The first two steps of this calculation are illustrated in Fig 3 The upper curve shows a recording for one observation window;

the abrupt change of the y(k) slope on the lower curve clearly

shows the instants when a transient phenomenon begins and stops

An example of the pulses during one observation window

is given in Fig 4, highlighting the damped sinusoidal form of the pulses, which was found in almost all of the recordings

To classify the pulses, two categories—single pulse and burst— were first considered In general, a burst is defined as a sequence

of distinct pulses but experimental results show that in most cases, a burst is formed by only two successive pulses, as shown

in Fig 4(b) Considering all the observation windows, one can determine the percentage of either single pulses or bursts, and thus their probability of occurrence

Since the approximate pulse shapes are damped sinusoids, a

pseudofrequency F pscan be defined as the frequency at which the PSD reaches a maximum value Consequently, the analysis can turn to the statistical distributions of the following charac-teristics: peak amplitude, pseudofrequency, duration, and IAT

D Description of the Successive Measurements

To draw pertinent conclusions from the study of impulsive noise, noise recordings from a certain number of vehicles are

Fig 4 Typical noise recording (a) Single pulse (b) Burst.

needed, since the noise characteristics are likely to vary with

the car brand and model We thus chose to take measurements

on a group of five upmarket cars from different manufacturers

in different countries Two of these cars, henceforth denoted as

CarG1 and CarG2, had gas engines; the other three—CarD3,

CarD4, and CarD5—were diesels The horsepower of the

dif-ferent motors ranged from 150 to 210 hp

Furthermore, in each vehicle, the measurements were taken

at a variety of different points, including the cigarette lighter,

the 12-V outlet, and the on-board computer power supply point

Indeed, one can expect that the noise also depends on the

elec-tronic equipment connected in the vicinity of the measurement

point and on the harness architecture Since the length of the

cables and the possible source of disturbances in the vicinity

of these points are quite different from one another, one can

hope that the measurement locations represent a true picture of

what happens in the network For the different cars, the typical

number of measurement points is 5 because, unfortunately, the

access points on the power network in new cars are quite limited

Preliminary measurements have shown that thousands of

pulses were stored in less than 1 s for a triggering level on

the order of few tens of millivolts, depending on the car Since

such a high number of events also occurred while the

vehi-cle was stationary and the motor idling, we have divided the

study into two parts, dealing with static and dynamic

condi-tions, respectively In the static condicondi-tions, few results are given

in Section III In the sequel, pulses characteristics in driving

conditions are emphasized In this case, the triggering level is

chosen high enough to be greater than the average peak value

of the pulses recorded in static conditions For these trials, the

measurements were taken during a 20-min trip in urban and

suburban driving conditions in dry or rainy weather, with

cer-tain systems (e.g., electric windows, fans, windshield wipers,

and headlights) activated under normal use conditions About

2000 observation windows were recorded at each measurement

point on the dc line while the vehicles were moving, leading

Fig 5 Recording of impulsive noise in static conditions.

Fig 6 Probability density of the characteristic parameters of noise in static conditions IAT distribution is given within a pulse sequence.

to about 104observation windows per car The main results are presented in Section IV

III IMPULSIVENOISE INSTATICCONDITIONS

In the stationary vehicle with an idling motor, impulsive noise was detected at the measurement points close to the on-board computer power supply point An example of a pulse sequence (i.e., a series of single pulses), measured on CarD5, can be seen on the recording shown in Fig 5 The various recordings show that the length of the pulse sequences may vary between

100 µs and 1 ms The probability densities of the characteristic

parameters of the impulsive noise shown in Fig 5 are given in Fig 6

The curves show that each single pulse has duration between

0.5 and 2 µs, and a pseudofrequency of 15 and 22 MHz for

CarD4 and 9 MHz for CarD5 For this very specific case of

impulsive noise observed under static conditions, we

distin-guished two distinct series of IAT; the first involved IAT within

a pulse sequence and the second involved IAT between two

se-quences The statistical study of the IAT between sequences

in-dicated that their average value is 10 ms The various recordings

show that the length of the pulse sequences may vary between

100 µs and 1 ms The IAT within a sequence being smaller than

100 µs, we concentrated on the distribution in that time interval,

since it has about the same duration as a code word As can be

seen in Fig 5, the series of pulses for CarD5 is quasi-periodic,

with the probability density function presenting a sharp

max-imum for an IAT of 50 µs (see Fig 6) For CarD4, the most

probable IAT is 30 µs, but the distribution function is more

spread out, extending from 25 to 50 µs.

The IAT distribution presenting narrow peaks and the

pseud-ofrequency being clearly identified, this suggests the presence

of an interference source rather than a random noise source

This could be, among other possible sources, either a clock or

impulse currents generated by modules used for the local

con-trol and diagnosis of electrical devices as well as to register and

display operating elements situated some distance away

On other recordings, data packets were clearly identified but

with a much lower peak amplitude However, since vehicle

com-munication systems use proprietary comcom-munication protocols

and since the access points for the measurements in the vehicles

were quite limited, it was impossible to identify these sources of

interferences As it appeared from measurements made on the

five cars during our experiments, the characteristics of these

in-terferences are quite different from one car to another It would

be necessary to make additional measurements on a much larger

number of cars to have an idea of the spread of the low-amplitude

pulse characteristics

IV STATISTICALPROPERTIES OFIMPULSIVE

NOISE INDYNAMICCONDITIONS

A Introduction

This section presents the statistical properties of all the

per-tinent parameters of the single pulses and bursts recorded when

the vehicles are moving The triggering threshold was increased

to 70 mV to avoid triggering on the numerous pulses also

oc-curring in stationary conditions, and even to 200 mV for cars

CarD4 and CarD5 The noise statistics presented in this section

will be, of course, only valid under these triggering conditions

The recordings show that the burst occurrence probability

is 4% and 6% for cars CarG2 and CarD4, respectively, 16%

for cars CarG1 and CarD5, and lastly, 26% for CarD3 This

probability is thus much lower than the one for single pulses

Based on the results obtained for CarG2, Fig 7(a) and (b)

rep-resents, respectively, the scatter plots of peak amplitude versus

pseudofrequency and the scatter plots of duration versus

pseud-ofrequency (single pulses and bursts are differentiated) In these

figures, the pseudofrequencies of the pulses, whether single

pulses or bursts, are spread out over the entire PLC bandwidth,

from several hundred kilohertz to 40 MHz

Fig 7 also highlights the similarity of the characteristics of

single pulses and bursts with respect to their pseudofrequency or

Fig 7 Scatter plot (a) Peak amplitude versus pseudofrequency plane (b) Duration versus pseudofrequency plane.

duration Since the same result was obtained for the other cars,

in the following discussion, no additional distinction will be made between single pulses and bursts We analyzed the pulse characteristics for each car statistically in order to identify the possible dispersion between the cars Depending on the intervals

of the variable, we wanted to analyze if either the cumulative distribution function (cdf) or the complementary cdf (ccdf) Future PLC systems will employ some adaptive cod-ing/modulation technique, and statistics based on a per-car basis

is interesting However, for the time being, such PLC modems are not yet commercially available, and, in addition, low cost

is an important constraint when developing new automotive de-vices We have thus preferred to perform a global analysis, in-tegrating all the data from all five vehicles in order to determine the average statistical distributions We then tried to find simple distribution functions based on well-known mathematical ex-pressions, which would fit the experimental distribution These functions will allow us to build a noise model for subsequent use in software for communication link simulators

B Peak Amplitude Distribution

The curves in Fig 8 show the ccdf of the peak values, deduced from the pulses recorded in each car The ccdf representation was chosen, instead of the cdf, because it clearly identifies the maximum values of the peak amplitude, which correspond to the most disturbing pulses The average distribution curve, denoted Experiment, was calculated for all the measurements on the five vehicles Two curves corresponding to measurements in two cars (G1 and D4) are also plotted They have been chosen since they are at the larger distance from the average curve, and this gives an idea of the spread of the experimental values

The pulse amplitudes are mostly between 0.5 and 1 V, with the probability of obtaining an amplitude greater than 1 V being between 1% and 8% If the low probabilities (typically less than

10−2) are excluded, the results indicate a low dispersion from one car to another

To find the mathematical expression of the distribution func-tions that would be most appropriate, six well-known

Fig 8 Complementary cumulative distribution of the amplitudes deduced

from values measured in two cars (curve CarG1 and CarD4), from all the

values measured in-vehicle (curve Experiment) The curve Model is based on

three gamma distribution functions.

functions—Gauss, gamma, Weibull, beta, Rayleigh,

exponential—have been tried However, a single function

could obviously not cover the entire interval of the possible

amplitude values A, and it was necessary to consider successive

subintervals This was done empirically by observing the

experimental curve of the probability density function and by

trying to find intervals in which the variation of the function

is smooth and does not present more than one maximum or

minimum For the amplitude A, three intervals were considered:

A < 0.31 V, 0.31 V < A < 0.67 V, and A > 0.67 V Then, to

find the most appropriate function, iterative trials are made The

function that minimizes the Kolmogorov–Smirnov statistics

is chosen For the distribution of the amplitudes, the gamma

probability density function, expressed mathematically in (2),

is the one that provides the best fit with the measurement results

y(x/a, b) = 1

b a Γ(a) e

where Γ() is the gamma function The values of the parameters

a and b are indicated in Fig 8 together with the probability P (A)

that A belongs to one of the three intervals Given the dispersion

of the results from one car to another, it did not seem necessary

to try a greater number of subintervals, nor to try various

dis-tribution function combinations It must also be emphasized

that, regardless of the variables studied, the gamma distribution

functions provided the best fit between the experimental and the

modeled results

C Pseudofrequency Distribution

The cumulative distribution of the pseudofrequency F ps

cal-culated from all experimental values (curve Experiment) is

plot-ted in Fig 9, together with the curve obtained from a modeling

based on gamma functions The pseudofrequencies are widely

spread, especially for CarD3 and CarG2, and are within the PLC

frequency band

Fig 9 Cumulative distribution of the pseudofrequencies calculated from the measurements and the statistical model.

Fig 10 Cumulative distribution of the pulse duration In-vehicle experimental results and simulation.

D Distribution of the Pulse Duration

The cumulative distribution of the pulse duration (curve

Ex-periment) calculated from all experimental values is plotted in

Fig 10 The extreme cases, corresponding to cars CarG1 and CarD4, do not show a large dispersion between cars We see that

50% of the pulses have a duration of less than 5 µs, and 99%

of the pulses last less than 20 µs The parameters of the gamma

functions used for the model are also given In most cases, a correlation between the pulse length and its pseudofrequency was observed, since the average number of sinusoids per pulse

is often between 4 and 5

E Distribution of the IAT

IAT is an important pulse characteristic for PLC communica-tion Indeed, to avoid two pulses disturbing the same code word,

Fig 11 Cumulative distribution of IATs.

data interleaving can be an interesting solution In this case, the

interleaving depth must be chosen in such a way that there is

little probability that two pulses will occur during the time of

an interleaved matrix Fig 11 presents the cdf of the IAT for all

vehicles (Experiment), for two extreme cases (cars G1 and D4).

The various intervals (expressed in log of their values) in which

the parameters of the gamma function were optimized are also

indicated

As Fig 11 shows, the spread of the IAT values is very wide,

ranging from a few microseconds to more than 1 min These

are not long IAT, which are disadvantageous for

communica-tion performance, but rather are IAT with an order of magnitude

measured in microseconds In fact, the average duration of an

OFDM symbol for this kind of communication is on the

or-der of 10 µs in the HP1.0 standard with its maximum rate of

14 Mb/s [15] It appears that four out of five vehicles behave

quite similarly in terms of IAT distribution, with a 20%–40%

probability of obtaining IATs under 100 µs, for example.

F Summary of the Characteristic Values

The first line in Table I summarizes the principal pulse

char-acteristics measured in the five vehicles The first column of

the table gives the burst occurrence probability In the next two

columns, the 50th percentile of the amplitude and the duration

are given, with the 90th percentile in parentheses For the IAT,

it was more interesting to calculate the 10th percentile rather

than the 90th percentile since the successive pulses with very

low IAT values risk disturbing the link The IAT has a strong

impact on the performances of the link For example, in

Home-Plug 1.0 [15], the duration of an OFDM symbol is 8.4 µs, and

RS and convolutional concatenated encoding is used on PHY

blocks based on 20 or 40 symbols Therefore if, for example,

two pulses separated by a time interval of 21 µs disturb a PHY

block of 20 symbols, the error-correcting code does not provide

any improvement in the error rate, because it could not correct

more than two disturbed symbols An example of application

of the impact of the noise on the system performances, and

especially on the maximum data rate and the bit rate, is given

in [11]

TABLE I

S UMMARY OF THE I N -V EHICLE AND I N -H OUSE C HARACTERISTIC P ARAMETERS

To our knowledge, there is not yet PLC modems that have been specifically developed for in-vehicle communication, and the first idea is to implement in-the-car, on-the-shelf modems optimized for in-house PLC However, as shown in Table I,

it appears that the pulses measured on the vehicles electrical networks have very different characteristics than those measured

on the in-house network [19]

The pulse duration and pulse amplitude are much smaller in-vehicle than in-house but the most critical point when optimizing the PLC physical layer will be related to the IAT, since the tenth

percentile is 21 µs in-vehicle compared to 7.1 ms in-house.

Since the successive OFDM symbols could be disturbed more frequently, the channel coding for in-vehicle PLCs must be different than the one used in-house

V CONCLUSION The objective of this study was to collect the data necessary for building a vehicle noise model to be implemented in a PLC simulation tool to allow the channel coding to be optimized An exhaustive study of the statistical properties of impulsive noise

on a vehicle power network was thus conducted Noise was recorded in five vehicles, either in a stationary vehicle whose motor was idling or in a moving vehicle For a stationary vehicle,

sequences of pulses, 100 µs to 1 ms long, were observed They

are likely due to interference from dedicated communications networks already implemented in the vehicle and from pulses generated by control-command devices as well The average amplitude of these pulses may greatly vary from one car to an-other, and additional measurement campaigns on a much larger number of cars are needed before drawing conclusions on the statistics of this low-amplitude noise For a moving vehicle, the triggering level was chosen equal to 70 or 200 mV, to be higher than the peak value of the pulses observed in stationary condi-tions The average distribution functions were plotted, and distri-bution functions corresponding to the experimental results were proposed Since available PLC modems have been developed mainly for in-house applications, the statistical properties of im-pulsive noise in the dc network inside a vehicle were compared

to those obtained on the main power network inside buildings

ACKNOWLEDGMENT The research reported in this paper was done in part within the framework of the Safe Transportation—Science and Technology

Research Center (Pˆole ST2: Sciences et Technologies pour la

S´ecurit´e dans les Transports) and in part within the Campus International de Recherche sur la S´ecurit´e et l’Intermodalit´e des Transports de surface (CISIT) project.

Proc IEEE ISPLC 2005, Vancouver, BC, Canada, Apr., pp 162–166.

[5] P A J van Rensburg, H C Ferreira, and A J Snyders, “An

experimen-tal setup for in-circuit optimization of broadband automotive power-line

communications,” in Proc IEEE ISPLC 2005, Vancouver, BC, Canada,

Apr., pp 322–325.

[6] W Gouret, F Nouvel, and G El-Zein, “Powerline communication on

automotive network,” in Proc IEEE VTC 2007 Spring, Apr., pp 2545–

2549.

[7] M Lienard, M O Carrion, V Degardin, and P Degauque, “Modeling and

analysis of in-vehicle power line communication channels,” IEEE Trans.

Veh Technol., vol 57, no 2, pp 670–679, Mar 2008.

[8] T P Diez, S A Alles, and R K Frazier, “Transient voltage

characteri-zation for automotive 42 volt power systems,” in Proc IEEE Int Symp.

Electromagn Compat., Aug 2000, vol 2, pp 921–926.

[9] A Schieffer, “Statistical channel and noise modeling of vehicular

DC-lines for data communication,” in Proc IEEE Veh Technol Conf., Tokyo,

Japan, May 2000, vol 1, pp 158–162.

[10] M O Carrion, M Lienard, and P Degauque, “Communication over

vehic-ular DC lines: Propagation channel characteristics,” in Proc IEEE ISPLC

2006, Orlando, FL, Mar., pp 2–5.

[11] V Degardin, M Lienard, P Degauque, and P Laly, “Performances of the

HomePlug PHY layer in the context of in-vehicle powerline

communica-tions,” in Proc IEEE ISPLC 2007, Pisa, Italy, Mar., pp 93–97.

[12] M O Carrion, V Degardin, M Lienard, and P Degauque,

“Characteri-zation and modeling of in-vehicle power line propagation channel,”

pre-sented at the 5th Int Conf ITS Telecommun., Brest, France, Jun 2005.

[13] V Degardin, M O Carrion, M Lienard, and P Degauque, “In-vehicle

power line communication: Impulsive noise characteristics,” presented at

the XXVIIIth General Assem URSI, New Delhi, India, Oct 2005.

[14] W Schulz and S Schwarze, “Comparison of CDMA and OFDM for

data communications on the medium voltage power grid,” in Proc IEEE

ISPLC, Limerick, Ireland, Apr 2000, pp 31–38.

[15] HomePlug white papers on Homeplug Web site (2008) [Online]

Avail-able: www.homeplug.org/products/whitepapers

[16] Limits and Methods of Measurement of Radio Disturbance Characteristics

for the Protection of Receivers Used on Board Vehicles, CISPR-25, 2002.

[17] P Torio and M G Sanchez, “Novel procedure to determine statistical

func-tions of impulsive noise,” IEEE Trans Electromagn Compat., vol 47,

no 3, pp 559–568, Aug 2005.

[18] M G Sanchez, L de Haro, M C Ramon, A Mansilla, C M Ortega,

and D Oliver, “Impulsive noise measurements and characterization in a

UHF digital TV channel,” IEEE Trans Veh Technol., vol 41, no 2,

pp 124–136, May 1999.

[19] V Degardin, M Lienard, A Zeddam, F Gauthier, and P Degauque,

“Clas-sification and characterization on impulsive noise on indoor power line

used for data communications,” IEEE Trans Consum Electron., vol 48,

no 4, pp 913–918, Nov 2002.

Virginie Degardin received the Engineer degree

from the Ecole Universitaire d’Ingenieurs de Lille, Lille, France in 2000, and the Ph.D degree from the University of Lille, Lille, in 2002.

She is currently an Associate Professor at the Telecommunications, Interference and Electromag-netic Compatibility (TELICE) Group, Institute of Electronics, Microelectronics and Nanotechnology (IEMN), University of Lille, where she is engaged

in research on both the theoretical and experimental prediction of propagation characteristics and the op-timization and performances of modulation and channel coding for power line

communications.

orthogonal frequency division multiplexing (OFDM), and spread spectrum tech-niques, for wireless local area network and power line communications.

Pierre Degauque (M’76) received the M.S and

Ph.D degrees from the University of Lille, Lille, France, in 1966 and 1970, respectively, and the Engi-neer degree from the Institut Superieur d Electronique

du Nord, Lille, in 1967.

He is currently a Professor at the University of Lille, where he is the Head of the Telecommunica-tions, Interference and Electromagnetic Compatibil-ity (TELICE) Group, the Institute of Electronics, Mi-croelectronics and Nanotechnology (IEMN) Since

1967, he has been engaged in research in the field

of electromagnetic wave propagation and radiation from various antenna con-figurations He was involved in research on radiation of antennas situated in absorbing media for geophysical applications His current research interests include radio propagation in confined areas, mines, and tunnels He is also en-gaged in research on electromagnetic compatibility, including wave penetration into structures and coupling to transmission lines.

Prof Degauque was the Vice Chairman of the International Union of Radio Science (URSI) Commission E, Electromagnetic Noise and Interference from

1999 to 2002 and the Chairman from 2002 to 2005.

Eric Simon received the Master’s degree in

electron-ics engineering from the Superior School of Elec-tronics (ESCPE), Lyon, France, in 1999, and the Ph.D degree in signal processing and communi-cations from the National Polytechnic Institute of Grenoble (INPG), Grenoble, France, in 2004 During 2005, he was a Teaching Assistant at the INPG and the following year he joined one of France Telecom R&D Laboratories as a Postdoctoral Fellow.

He is currently an Associate Professor at the Institute

of Electronics, Microelectronics and Nanotechnol-ogy (IEMN), University of Lille, Lille, France His current research interests include the area of wireless and digital communications.

Pierre Laly received the Licence’s degree in

telecom-munication network from the Institut Universitaire de Technologies (IUT) de Lille, Lille, France, in 2002 From 1991 to 1999, he was with Mi-cropuce, Inc He joined the Institute of Elec-tronics, Microelectronics and Nanotechnology (IEMN)/Telecommunications, Interference and Elec-tromagnetic Compatibility (TELICE), University of Lille, Lille, in 2000, where he is currently an Engineer His research interests include measure-ment techniques for wire or wireless communication systems.