This paper presents the results of a series of laboratory measurements, carried out to study how the ground-penetrating radar (GPR) signal is affected by moisture variation in wood material. The effects of the wood fibre direction, with respect to the polarisation of the electromagnetic field, are investigated. The relative permittivity of wood and the amplitude of the electric field received by the radar are measured for different humidity levels using the direct-wave method in wide angle radar reflection configuration, in which one GPR antenna is moved while the other is kept in a fixed position. The received signal is recorded for different separations between the transmitting and receiving antennas. Dielectric constants estimated from direct waves are compared to those estimated from reflected waves: direct and reflected waves show different behaviour when the moisture content varies, due to their different propagation paths.
Ground-penetrating radar (GPR) is an effective technique that uses electromagnetic waves to obtain three-dimensional images of natural or man-made structures and subsoil. It is employed in a large variety of applications for which non-invasive and non-destructive investigations are required. Examples of applications are surveying of transport infrastructures and buildings, detection and location of utilities, inspection of construction materials, geological and geotechnical investigations, archaeological prospecting and cultural-heritage diagnostics, detection of landmines and unexploded ordnance, planetary exploration and more (Benedetto and Pajewski, 2015; Persico, 2014).
Recently, GPR started being used for the non-destructive evaluation of moisture content in wood material. The most common causes of wood deterioration are biological, due to infestation of fungi and insects. There are several factors influencing the biological degradation of wood caused by fungi and insects in addition to moisture, for example, the source of infection, substrate (food), oxygen, temperature and more. However, the moisture content is recognised as one of the most critical factors for the development of such organisms. Fungal spores do not germinate readily on wood if the moisture content is below the fibre saturation point, commonly reached around 25–30 %. The percentage of moisture that is required for wood rotting fungi to flourish depends on the species of fungi and on the kind of wood. It is therefore apparent that the non-destructive evaluation of moisture content is of primary importance for the preservation of timber structures.
Few works in the literature are concerned with the GPR inspection of wood. In
Lualdi et al. (2003), Muller (2003), Sbartaï (2011), Martínez-Sala
et al. (2013b), Mai et al. (2015), the properties of wood were estimated
using reflected-wave methods. In Lualdi et al. (2003), GPR was used to detect
timber beams and evaluate the type and size of their connection to a bearing
wall. In Muller (2003), GPR was employed for the inspection of timber bridges
in order to detect piping and rotting defects. In Martínez-Sala et
al. (2013b), GPR was used on samples of sawn timber of different species
(densities) and interesting results were found: the propagation velocities,
as well as the amplitudes of the reflected waves, were always smaller when
the electric field was longitudinal to the grain rather than transverse to
it. However, when the field propagated in a random direction, the
electromagnetic parameters did not differ significantly. In Mai et
al. (2015), laboratory measurements were carried out with the aim of studying
the sensitivity of electromagnetic-wave propagation to moisture variation and
fibre direction, in spruce and pine wood samples. The relative permittivity
(dielectric constant) was measured using the resonance technique at
1.26
In Laurens et al. (2005), Sbartaï et al. (2006a, b), Martínez-Sala et al. (2013a), direct-wave methods were used for the non-destructive evaluation of concrete properties, with successful results. Direct-wave methods are of practical interest, because sometimes it may be difficult to detect the signal reflected by a sample when applying the technique on site.
A preliminary example of application of the direct-wave approach to wood assessment can be found in Mai et al. (2015). In that paper, tests were carried out on a sample of spruce with a humidity of 12 %. Measurements were performed with the electric field orthogonal to the wood fibres. The obtained results showed that the direct-wave signal is measurable. In addition, the permittivity values estimated by employing the direct-wave technique turned out to be lower than those estimated from the reflected waves.
Our work focuses on using the GPR direct wave to estimate the properties of wood. Results are compared with those obtained by employing a reflected-wave approach. Different moisture-content conditions are reproduced in the laboratory and analysed. The effects of the wood fibre direction, with respect to the polarisation of the electromagnetic field, are investigated. An interesting feature of the direct-wave method is that the operator simply has to measure the wave propagating between the transmitter and receiver, without needing a reflector at the bottom of the sample or information about the sample thickness.
The electromagnetic signal received by GPR in the presence of a wood sample is affected by many parameters, such as moisture content, wood density, temperature and direction of fibres (Sahin and Nürgul, 2004; Laurens et al., 2005; Kasal and Tannert, 2010). They influence the electromagnetic-field attenuation, phase shift and polarisation (Lundegren et al., 2006).
Let us consider a plane electromagnetic wave propagating through wood in the
As already mentioned, electromagnetic waves propagate in a vacuum at an
approximate speed of 0.3
GPR measurements on the wood sample using ground-coupled antennas
and the WARR technique.
Humidity by mass water as a function of the time of immersion into the water.
A-scans showing the superposition of the direct-air, direct and reflected waves measured over the sample when the polarisation of the electric field is orthogonal to the fibres and at a 12 % humidity level by mass water.
B-scans showing the direct-air, direct and reflected waves measured over the sample when the polarisation of the electric field was perpendicular to the fibres and at a 12 % humidity level by mass water.
Determination of the propagation velocity for the direct wave from
the arrival times. Both configurations with electric field parallel and
perpendicular to the fibres are considered. In this case the humidity level
was 18.18 %.
Schematic view of the distances between antennas (blue line), thickness of the wood sample (green line) and reflected-wave path (black line).
Relative permittivity as a function of humidity by mass water, estimated using the direct-wave (WARR) and reflected-wave methods for both polarisation cases.
Relative permittivity of wood for different levels of humidity by mass water, for direct- and reflected-wave approaches.
Measurements start at a humidity level of the wood sample equal to 12 %, known as the reference humidity (water content) used for wood characterisation. We measured the reference humidity to be 12 %, at the end of the experiments by putting the sample to the oven and finding the weight in anhydrous mode. The calculated density at zero humidity is used to correct the humidity values. Afterwards, the sample is immersed in water to gradually increase its moisture content. GPR experiments are then repeated at different humidity levels.
Humidity by mass water (%) is calculated by adopting the following
expression (Moron et al., 2016):
Figure 2 shows the humidity by mass water of the sample, as a function of the time of immersion into the water. The measurements are performed at the humidity levels listed in Table 1.
When applying the WARR technique, a radar antenna is kept in a fixed position
and the other antenna is moved on the wood surface with a 1 cm step. The
distances between the two antennas vary from 16 to 26
For the WARR technique, the propagation velocity is estimated from the arrival times of the direct waves, measured at difference distances between the antennas (the arrival time is the instant corresponding to the first and highest positive peak in the radargram). In particular, the propagation velocity is estimated as the slope of the linear regression of the arrival time of the direct wave, as a function of the distance between antennas. This is shown in Fig. 5, for both polarisation cases and a level of humidity equal to 18.18 %.
For the reflected wave, the propagation velocity
For the reflected wave (
From the combination of Eqs. (7) and (8) it is possible to find the
propagation velocity inside the wood sample, as follows:
As mentioned in Sect. 2, the wood relative permittivity is measured for different humidity levels (ranging from 12 to 64.5 %) and polarisation cases (electric field orthogonal and parallel to the wood fibres). Results are summarised in Table 1 and plotted in Fig. 7.
When the direct-wave method is used, the estimated value of the relative permittivity does not significantly change if the polarisation is rotated. When the electric field is parallel to the fibres, the permittivity values are systematically higher than those measured when the electric field is orthogonal to the fibres. Wood is an anisotropic media, so the dielectric properties of it are strongly influenced from the polarisation of electric field in relation to wood grains; moreover these properties are influenced by cellulose and mannan in the case of parallel polarisation, but in a transverse direction the dielectric properties are influenced by lignin. Lignin has lower dielectric properties than cellulose. Therefore, it is expected that the values of dielectric constants in the parallel polarisation are more influenced by humidity than in a transverse direction. In the case of the reflected wave, the electric field can be polarised exactly to the wood grains.
The increase of relative permittivity versus moisture content is piecewise linear, with a slope change occurring when the humidity level is about 18 %, in agreement with a previous publication where more samples were considered (Mai et al., 2015).
For the reflected-wave method, the increase of relative permittivity versus moisture content is piecewise linear as well, with a higher slope than in the case of the direct-wave method. Moreover, the slope strongly depends on the polarisation of the electromagnetic field and this is in agreement with Martínez-Sala et al. (2013b), Mai et al. (2015). When the electric field is orthogonal to the wood fibres, a slope change occurs at a humidity level of about 18 %, corresponding to the fibre saturation point. The slope change is less visible and seems to occur at higher humidity levels when the electric field is parallel to the wood fibres; this is again in agreement with Martínez-Sala et al. (2013b), Mai et al. (2015).
At all humidity levels, the permittivity values measured by the reflected-wave method are consistently higher than those measured by the direct-wave method. For both methods, the direction of the fibres does not affect the wood permittivity when the moisture content is low, then it becomes more important in the presence of higher humidity levels.
It is interesting to notice that the results of the reflected-wave method are closer to the direct-wave curves when the electric field is orthogonal to the wood fibres. When the electric field is polarised in a transverse direction, the dielectric properties of wood are influenced by lignin. Lignin has lower dielectric properties than cellulose and this could be the reason for this small change.
The obtained results show that direct waves in wood behave differently than reflected waves. This happens because the direct and reflected waves follow different propagation paths: the direct waves propagate in the top layer of the sample and the effect of the electromagnetic-field polarisation is small; the reflected waves propagate through the whole sample and, due to the anisotropy of wood, the polarisation has a stronger effect on the results.
When the electric field is orthogonal to the wood fibres, direct waves can be distinguished even when the humidity levels are above 60 %. When the electric field is parallel to the wood fibres, the direct-wave arrival time cannot be detected for humidity levels higher than 43 %. We tested humidity levels higher than 43 %, but in such conditions a high dissipation of electromagnetic energy occurs, the signal is completely attenuated in the parallel polarisation and it is not possible to extract signal parameters.
A further goal of this work is to study how the distance between the radar
antennas affects the amplitude of the received signal. For each considered
humidity level, the amplitude of the direct wave is then measured with
antennas placed at 30 different distances. In Fig. 8, the direct-wave
amplitude normalised to the amplitude of the direct-air wave is plotted as a
function of the distance between transmitting and receiving antennas, when
the humidity by mass water is 18.18 %. As expected, the amplitude shows
an exponential attenuation when the distance increases. In Fig. 9, the
normalised amplitude of the direct wave is plotted as a function of the
humidity level for both parallel and orthogonal polarisation cases, when the
distance between the antennas is 11 and 16
Amplitude of the signal received by the GPR, as a function of the distance between transmitting and receiving antennas (WARR method, 18.18 % humidity by mass water).
Normalised amplitude of direct wave with respect to humidity, for perpendicular and parallel polarisation of the electric field.
For small humidity levels, the normalised amplitude increases with moisture content, then when moisture content is further increased, the normalised amplitude starts to decrease (this happens at about 30 and 25 % humidity by mass water for orthogonal and parallel polarisation, respectively). This phenomenon should be investigated more in depth by carrying out further measurements on different kinds of wood (with different densities) in order to have a clear picture of it.
In this work, the sensitivity of ground-penetrating radar (GPR)
signal to moisture variation in wood material was investigated. The relative
permittivity of a
Results obtained by using direct waves in wide angle radar reflection (WARR) configuration, in which one GPR antenna is moved while the other is in a fixed position, were compared to results obtained by using reflected waves in the so-called fixed offset configuration in which the distance between GPR antennas is fixed. Additionally, when the WARR method was applied, it was investigated how the attenuation of the received signal varies as a function of the distance between the radar antennas.
The presented results prove that direct and reflected waves have different behaviours when the moisture content varies, due to their different propagation paths. Overall, when the humidity levels increase, the difference between the permittivity values estimated by using the reflected- and direct-wave approaches becomes larger.
For the reflected waves, the wood anisotropy affects the variation of the relative permittivity as a function of the moisture content; the effect is stronger when the electric field is parallel to the wood fibres. This is in good agreement with results available in the literature. Regarding direct waves, the measured values of the relative permittivity turn out to be weakly affected by the polarisation of the electromagnetic field. They are close to the values obtained by using reflected waves with the electric field orthogonal to the wood fibres. Apparently, the propagation paths are similar in the two cases.
Overall, our results show that the proposed measurement approach is effective at estimating the permittivity behaviour of wood material as a function of moisture content. The GPR technique is promising for moisture evaluation in timber structures and their early-stage diagnosis.
GPR data in wood, relative to this paper are available in the online
repository of IGEWE,
The authors are grateful to COST (European Cooperation in Science and
Technology,