2 MULTIPATH FROM SPECULAR REFLECTION ON GROUND

Interferences between the direct plane wave emitted by a radio source and detected in an antenna, and its specular reflection on a horizontal surface – flat ground or ocean – have been known to produce oscillations since the first days of radio interferometry (Bolton Reference Bolton1982; Sullivan III Reference Sullivan III, Cornwell and Perley1991). Writing ξ the difference in path length between the interfering waves, ν the frequency and λ the wavelength, here ~ 21 cm, the time difference between the two interfering waves is Δt = ξ/λν. Introducing a parameter ε to account for the attenuation resulting from the reflection on ground and from the lesser gain of the side lobe in which the reflected wave is detected, the dependence on time t of the detected signal reads

\begin{eqnarray*} S&&=|e^{i2\pi \nu (t-\frac{1}{2}\Delta t)}+\epsilon e^{i2\pi \nu (t+\frac{1}{2}\Delta t)}|^2\\ &&=|e^{i2\pi \nu t}|^2|e^{i\pi \xi /\lambda }+\epsilon e^{i\pi \xi /\lambda }|^2\\ &&=1+\epsilon ^2+2\epsilon cos(2\pi \xi /\lambda ). \end{eqnarray*}

In a time interval centred on t ₀ (where ξ = ξ₀) the time dependence of the oscillation reads therefore

(1) \begin{equation} {} S(t)=1+\epsilon ^2+2\epsilon cos\lbrace 2\pi \lambda ^{-1}[\xi _0+(t-t_0)d\xi /dt]\rbrace \end{equation}

Describing the oscillation as a sine wave, sin[2π(t − t ₀)/T + φ], implies a period T = λ/(dξ/dt) and a phase φ = π/2 + 2πξ₀/λ. In order to have T positive, one prefers to write

(2) \begin{equation} {} T=\lambda /|d\xi /dt| \quad\text{ and }\quad \varphi =\pi /2\pm 2\pi \xi _0/\lambda \end{equation}

where the + sign is for ξ increasing with t and the − sign for ξ decreasing with t. Relation 2 implies a fundamental relation between T and dφ/dt

(3) \begin{equation} {} T|d\varphi /dt|=2\pi \end{equation}

which is characteristic of the multipathing effect.

Note that Relation 2 allows for an evaluation of dξ/dt from measurements of T and/or dφ/dt but not for a measurement of ξ itself: the difference in path length can only be obtained up to an unknown integer number of wavelengths. Equivalently, φ is only defined up to an unknown integer factor of 2π.

From Figure 1, ξ = 2Dsin(h) where D is the distance of the antenna to ground and h the elevation of the source.

Figure 1. Upper panel: geometry of specular reflection on ground into a dish centred in O and having image O′ in the ground mirror. Lower panel: departure from exact specular reflection (mean ray), definition of the angles r and θ.

As h increases with t in the morning and decreases with t in the afternoon, so does ξ. At a same time t, from one day to the next, one expects therefore φ to increase in the morning in the Northern hemisphere between December 22nd and June 21st. Changing from morning to afternoon, or from Northern to Southern hemisphere or from December-June to June-December changes the sign of the daily variation of φ.

If the hypothesis of specular reflection is slightly relaxed, reflections with an impact point farther away from the antenna than the specular impact (i.e. reaching the dish at a smaller angle with respect to the main lobe) are favoured with respect to reflections with an impact point closer than the specular impact. The reason is not only from pure geometry arguments but also because the reflected wave reaches the dish at large angle with respect to the beam and the antenna gain, on average, decreases with this angle. This causes the mean impact to be behind the specular impact and the path difference ξ to take larger values than in the specular case; as D is proportional to ξ, it is overestimated accordingly.

The effect is easily simulated by describing the deviation from specular reflection by a Gaussian dependence of the reflection probability on the angle r of the reflected wave with respect to the specularly reflected wave, $exp(-\frac{1}{2}r^2/\sigma _r^2)$ and the decrease of the antenna gain by another Gaussian dependence on the angle θ between the reflected wave and the antenna axis, $exp(-\frac{1}{2}\theta ^2/\sigma _\theta ^2)$ (Figure 1). Moreover, accounting for the irregularities of the reflecting surface can be approximated by a smearing of ξ using a third Gaussian, $exp[-\frac{1}{2}\Delta \xi ^2/(\xi \sigma _{sm})^2]$ .

An important consequence of the above mechanism is the existence of a correlation between the periods of simultaneous oscillations independently detected by two distant observatories such as Ha Noi and Learmonth.

Consider two radio telescopes operated at a same frequency at heights D ₁ and D ₂ above a flat ground in observatories located at respective longitudes and latitudes (ψ₁, ζ₁) and (ψ₂, ζ₂).

Writing h′ = |dh/dt|, the periods read $T_{1,2}=\frac{1}{2}\lambda /[D_{1,2}h_{1,2}cos(h_{1,2})]$ . In the approximation of a circular Earth orbit, calling δ the Sun declination and H = t + ψ the hour angle sin(h) = sinδsinζ + cosδcosζcosH (H = 0 when the Sun crosses the meridian plane). Hence,

(4) \begin{equation} T=T^*/[cos\delta |sin(t+\psi )|] \end{equation}

with $T^*=\frac{1}{2}\lambda /(Dcos\zeta )$ being a constant for each observatory. Writing ρ = T/(T*cosδ), ρ₁ = 1/|sin(t + ψ₁)| and ρ₂ = 1/|sin(t + ψ₂)| are trivially correlated, implying a correlation between the periods measured simultaneously by both observatories. If the two observatories are exactly at the same longitude, ρ₁ = ρ₂ at any time. In practice, the longitudes of the two observatories should not be too different for them to have a chance to observe the Sun simultaneously for long periods of time. In the Ha Noi/Learmonth case, the two latitudes are nearly opposite ( ± 21.6° ± 0.6°) and the two longitudes are nearly equal ( $110^\circ {\text{E}}\pm 4^\circ$ ). In the approximation where ψ₁ = ψ₀ − Δ, ψ₂ = ψ₀ + Δ, 0 < Δ ≪ 1 rad (observatory 1 being east of observatory 2) and writing H ₀ = ψ₀ + t the mean hour angle,

(5) \begin{equation} \rho _1=1/|sin(H_0+\Delta )| \quad \text{ and }\quad \rho _2=1/|sin(H_0-\Delta )| \end{equation}

Around noon, the elevation is stationary and the period of the oscillations takes very large values outside the range where they can be detected. In the morning, H ₀ < −Δ, the elevation, and therefore the period of the oscillations increases with time. In the afternoon, H ₀ > Δ, they decrease. Changing H ₀ into − H ₀ changes ρ₁ into ρ₂. In the morning, both periods increase, that of observatory 1 faster than that of observatory 2. In the afternoon, both decrease, that of observatory 2 faster than that of observatory 1. This is schematically illustrated in the upper panel of Figure 2. The predicted correlation is essentially independent of the season during which observations are made: the only seasonal contribution is from the cosδ term which remains confined between 0.92 and 1 over the whole year and has therefore very little effect.

Figure 2. Correlations observed between the periods of oscillations measured in two observatories at nearby longitudes. Upper panel: schematic illustration of the main features; the angle between the morning and afternoon lines is a measure of the difference of longitude between the two observatories. Lower panel: correlation observed in Hiep et al. Reference Hiep2013 between Learmonth (ordinate) and Ha Noi (abscissa); the dotted line displays the model prediction for morning oscillations using respective D values of 7 m and 6 m for Learmonth and Ha Noi respectively.

3 OBSERVED OSCILLATIONS IN LEARMONTH AND HANOI

When applied to a real observatory, the parameters that characterize the oscillations are strongly dependent on the environment of the antenna. In the cases studied here, Ha Noi and Learmonth, the distance of the antenna to the reflecting surface is between 5 and 20 m, the latitude is ~ ±22° and the wavelength is 21 cm. Hence T* is between 1 and 5 min. The method used to detect oscillations requires their period to be of the order of a few minutes, say 2 to 10 minutes typically, excluding an interval of 1 to 2 hours around local noon, during which the period of the oscillations is too large to be observed. However, the rest of the time, one deals with a broad range of elevations, allowing the impact point on ground to reach close to the antenna.

The Learmonth antenna, 2.4 m (8 ft) in diameter, (Figure 3 left) is located in an airport on a pole erected some 7.5 m above a flat ground. The only nearby building is located south of the antenna, outside the range of azimuths toward which the antenna is pointing. On the contrary, the Ha Noi antenna, 2.6 m in diameter, (Figure 3 right) is on top of a small building, some 20 m above ground and some 5 m above the flat roof, in a urban environment. One would therefore expect the multipath pattern observed at Learmonth to be considerably simpler and easier to describe than that observed in Ha Noi.

Figure 3. Sites of the observatories in Learmonth (left, courtesy of Dr Owen Giersch) and Ha Noi (right). The lower panels show satellite maps of the two sites (source: Google map).

The data used in the present work cover the period October 24th 2013 to January 31st 2014 for both Ha Noi and Learmonth. In addition Learmonth data collected during the 10 central days of each month of the year have been included in the analysis. For both Ha Noi and Learmonth, the signal to noise ratio is of the order of 500. Details of the procedure of data reduction are available in Phuong et al. Reference Phuong2014 a,b.

After subtraction of solar flares and occasional interferences of human origin, the time dependence of the antenna temperature, averaged over the bandwidth, is searched for oscillations having periods in the 2 to 10 minutes interval. The method consists in evaluating, for each independent measurement, the amount of oscillation that the data can accommodate. Each oscillation is evaluated over a 20 min interval centred on the particular measurement i and is characterized by an amplitude A_i , a phase φ _i , a period T_i and a chi square describing the quality of the fit, χ² _i . The significance of such oscillations can then be assessed objectively from the values of A_i and χ² _i without requiring human intervention. For each period T and each measurement i one calculates the mean value M_i and the rms deviation with respect to the mean R_i in a time interval centred on measurement i and having a width T. In a second step, a fit of the antenna temperature is performed over a 20 min time interval centred on measurement i to a form M_i + ηR_isin[2π(t − t_i )/T + φ]. Here t spans the 20 min interval while t_i is the time of measurement i. Parameters η and φ measure the relative amplitude and phase of the oscillation respectively. The problem being linear in ηcosφ and ηsinφ allows for an easy explicit calculation of the parameters. Figure 4 illustrates the procedure.

Figure 4. A typical oscillation. The upper panel shows the data (red) together with the fit (blue) and M and M ± R (black). The lower panel compares data (blue) and fit (red) after subtraction of M and division by R.

Significant oscillations are defined as having a small χ² _i value, a large η value (meaning that the oscillation accounts for a major fraction of the signal fluctuation in the 20 min interval) and a large ηR_i /M_i value (meaning that the amplitude of the oscillation exceeds noise level). Different selection criteria have been tried and the robustness of the corresponding conclusions has been ascertained.

Distributions of time versus period using sensible selection criteria display very clear patterns that are illustrated in Figure 5 and follow the same trend as expected from specular reflection on ground. Examples of the evolution of the phase of the oscillations from one day to the next are displayed in Figure 6. Here again, the dependence on season, hemisphere and time in the day is as expected from specular reflection on ground.

Figure 5. Time versus period scatter-plots. Upper panel: Ha Noi data (red) collected between October 25th and December 17th, 2013 . The lines are specular reflection multipath predictions for D = 6 m (roof) and D = 25 m (ground). Lower panel: Learmonth data (red) collected in the 10 central days of May 2012. The blue lines are ground specular reflection multipath predictions for D = 8.5 m.

Figure 6. Dependence on the date of the phases of oscillations observed under different conditions. The lower right panel displays the daily phase increment rather than the phase itself and is seen to decrease when approaching the Winter solstice as expected (its large value results from the large associated D value).

4 COMPARISON BETWEEN OBSERVATIONS AND PREDICTIONS

Having illustrated by a few examples in Figures 5 and 6 the good qualitative agreement between the observed oscillations and the predictions of a multipath model assuming perfect specular reflection on ground, we now attempt a more quantitative analysis of the effect. The measurements of the period and phase of the oscillations provide independent evaluations of the altitude D of the antenna above ground. From $T=\lambda /|d\delta /dt|=\frac{1}{2}\lambda /(D|dh/dt|cos(h))$ one obtains

(6) \begin{equation} D=\frac{1}{2}\lambda /(T|dh/dt|cos(h)) \end{equation}

Relation 6 relates the height D of the antenna above the reflective surface to the measured value of the period of the oscillations under the hypothesis of specular reflection. Figure 7 displays the distributions of D obtained this way for the oscillations observed in Learmonth and Ha Noi. The former is dominated by ground reflections while the latter displays a more complex structure revealing reflections from the observatory roof in the morning and late afternoon and from ground in the early afternoon. Knowing D, it is easy to map the impact coordinates on ground, x = Dcos(a)/tan(h) and y = Dsin(a)/tan(h). They do not display any particular structure in the Learmonth case, which is consistent with a flat ground, while revealing clearly distinct regions in the Ha Noi case, that are unambiguously associated with the topography of the environment as shown in Figure 3.

Figure 7. D distributions obtained from the Learmonth (upper panel) and Ha Noi (lower panel) data in November-December 2013. The blue lines show model predictions allowing for small departures from exact specular reflections (see text).

Using reasonable values for the parameters describing a small departure from exact specular reflection on ground, it is easy to obtain a good description of the D distributions as illustrated in Figure 7 where a common value of 45° has been used for σ_θ while σ _r takes values between 9° and 16° and σ _sm ~ 10%. The quality of the data does not allow to measure these parameters precisely and other combinations of their values can be found that give also acceptable results. However, in all cases, the departure from exact specular reflection that can be accommodated remains small, not exceeding 20°. An effect of the inclusion of such departure is to significantly lower the estimate of D with respect to exact specular reflection: from 8.3 m to 7.7 m in the case of Learmonth and, in the case of Ha Noi, from 6.2 m to 5.7 m for the roof and from 26 m to 21 m for ground, improving significantly the agreement with real dimensions (respectively 7.5 m, 5.6 m and 17.7 m).

The correlation expected between oscillations observed in the morning at Learmonth from ground and in Ha Noi from reflections on the observatory roof is illustrated in Figure 2 (lower panel). The agreement with observation is remarkable given the crudeness of the model used.

Relation 3, which relates independent measurements of the period and phase of the observed oscillations, offers a crucial test of their multipath nature. Note that the path difference between the direct and reflected waves is of the order of magnitude of D for the rather large values of the Sun elevation associated with the observed oscillations, meaning several tens of wavelengths. As remarked earlier, the phase of the oscillation is measured up to an integer multiple of 2π and it is not possible to measure D directly from a single phase value but dφ/dt is simply evaluated from the phase difference between two successive measurements. The distribution of (2π)⁻¹ T|dφ/dt| obtained this way is displayed in Figure 8 for Learmonth and Ha Noi oscillations having amplitudes in excess of 3‰, giving in both cases very strong evidence for the multipath nature of the effect. Mean(rms) values of 1.01(0.11) and 1.00(0.13) are obtained for Learmonth and Ha Noi respectively, giving strong evidence for the multipath origin of the observed oscillations. Note that Ha Noi data mix reflections from ground and from the observatory roof, spanning a broad range of D values. The Learmonth data cover the whole year and the simple topography implies reflections from a flat ground with a well defined D value, 8.24 m on average. It fluctuates by only ± 0.37 m over the year and the rms value of its distribution is 1.21 m on average. Comparing the summer months (November to February) with the winter months (May to August) for the retained oscillations, the mean elevation of the Sun is found to vary from 49° to 35° and the mean amplitude of the oscillations from 5.0‰ to 6.8‰ while the width of the distribution of (2π)⁻¹ T|dφ/dt| remains constant to better than 10% of its value. The number of retained oscillations is nearly twice as large in winter than in summer.

Figure 8. Distribution of (2π)⁻¹ T|dφ/dt| for oscillations having amplitudes in excess of 3‰ for Learmonth (upper panel) and Ha Noi (lower panel) data. The Ha Noi distributions display separately ground reflections (black) and roof reflections (blue in the morning and red in the afternoon). The scale of ordinate is linear for Learmonth and logarithmic for Ha Noi.