2.1.

Derivation of Coupled Electric Field Integral Equations

In accordance with the surface equivalence principle,²¹ the original scattering problem can be replaced by equivalent exterior and interior problems. In the equivalent exterior problem, the boundary is replaced by equivalent electric $({\mathit{J}}_1=\widehat{\mathit{n}}\times {\mathit{H}}_1)$ and magnetic $({\mathit{K}}_1={\mathit{E}}_1\times \widehat{\mathit{n}})$ surface currents, which reproduce the fields in region 1 in combination with the original source. Note that the electric field in region 1 is ${\mathit{E}}_1={\mathit{E}}^{\mathrm{inc}}+{\mathit{E}}^s$, where ${\mathit{E}}^{\mathrm{inc}}$ and ${\mathit{E}}^s$ are the incident and scattered electric fields, respectively; and the magnetic field is ${\mathit{H}}_1$. Here, $\widehat{\mathit{n}}$ is the unit normal vector pointing into region 1. Null fields are produced in region 2, which allows that region to be replaced with any desired material. It is convenient to replace region 2 with a vacuum, thus yielding currents that radiate in unbounded space (and permitting use of the free-space Green’s function^21–23). In the equivalent interior problem (opposite the exterior problem), the boundary is replaced with equivalent electric $({\mathit{J}}_2=-\widehat{\mathit{n}}\times {\mathit{H}}_2)$ and magnetic $({\mathit{K}}_2={\mathit{E}}_2\times -\widehat{\mathit{n}})$ surface currents, which reproduce the fields ${\mathit{E}}_2$ and ${\mathit{H}}_2$ in region 2. Null fields are produced in the exterior region, thus permitting region 1 to be replaced with any desired material. It is convenient to replace region 1 with $\epsilon$ and $\mu$ yielding currents that radiate in unbounded space. The continuity of transverse electric and magnetic fields at the rough interface implies that ${\mathit{J}}_1=-{\mathit{J}}_2=\mathit{J}$ and ${\mathit{K}}_1=-{\mathit{K}}_2=\mathit{K}$, yielding a system of coupled electric field integral equations, namely

2.2.

Impedance Boundary Condition

The system of coupled electric field integral equations in Eq. (1) can be solved using the MoM; however, this is extremely prohibitive. Because the rough surfaces of interest are very large compared to the wavelength of the field, the size of the resulting matrix equation, formed by discretizing Eq. (1), is extremely large, making computation of the solution very difficult. However, if $R_{\min }\gg \delta$ (where $R$ is the radius of curvature and $\delta$ is the skin depth), then an approximate impedance boundary condition (IBC) can be used to reduce Eq. (1) to a single equation with one unknown. This reduces the size of the matrix equation by a factor of 4. The limits of applicability of the IBC can be found in Yuferev et al.²⁵ If the IBC is valid (which it is for the surfaces analyzed in this research), the electric and magnetic surface currents are related by

Substituting Eq. (3) into the first equation in Eq. (1), specializing the resulting expression to the ${\mathrm{TM}}^z$ polarization case, and simplifying yields the desired electric field integral equation:

Substituting in the simplified expressions for the electric and magnetic vector potentials, we get

2.3.

MoM Solution

In this analysis, the MoM is used to solve Eq. (4) for the unknown electric current. The MoM consists of two steps—expansion and testing. In the expansion step, a set of basis functions with unknown weights are chosen to expand the unknown current. The resulting system is then tested using another set of functions to solve for the unknown expansion weights. Note that at least first-order differentiability is required for basis and testing functions to overcome the Green’s function source-point singularity [$H_1^{(2)}(x)\sim 1/x$ as $x\to 0$];²¹ thus, pulse (rectangular) basis and delta testing functions will suffice. Substitute $J_z(x^{\prime })=\sum _{n=1}^N{\alpha }_n{f}_n(x^{\prime })$ into Eq. (5), where ${\alpha }_n$ are the unknown, complex basis function weights and $f_n$ is a unit pulse defined over cell $n$, namely

Then, testing the resulting equation [i.e., ${\int }_C\delta (x-x_m)\{·\}\mathrm{d}x$] and simplifying yields

Equation (7) can now be written in matrix form as

The elements of $[Z_{mn}]$ are remarkably physical. For instance, element $m$, $n$ models how the source located in cell $n$ affects the field observed at point $(x_m,y_m)$. Due to electromagnetic reciprocity, the impedance matrix is symmetrical. Physical intuition dictates that the closer the source and observation point are to each other, the more significant the coupling between the two is. This intuition is captured in the impedance matrix, which although generally full, is highly diagonal, i.e., the “self” terms (source and observer at same location) are dominant. If the surface is perfectly reflecting ($\eta =0$) or perfectly conducting, the impedance matrix contains only the terms involving ${\eta }_0$. The terms involving $\eta$ are correction terms accounting for a surface with a nonzero impedance. Note that for metals that are highly reflective, the $\eta$ terms are significantly smaller than the terms involving ${\eta }_0$.

The scattered field at an observation point $(x,y)$ in the far zone can be expressed as

The interested reader is referred to Harrington,²³ which outlines the methodology used in the derivation of Eq. (12).

4.1.

Experimental Validation of Simulated Scattering Data

Simulations were performed to compute the statistical scattered radiation in the far field for the two rough targets when illuminated at different angles of incidence. In these simulations, the rough-surface statistics obtained from the characterization procedure discussed in Sec. 3 were used. The simulation results were verified against experimental measurements from the CASI. To ensure a high-fidelity validation of the MoM simulation results, the CASI incident laser beam parameters and the source-to-sample distance were carefully determined and used in the simulations. From this analysis of the CASI, a unit-amplitude, collimated Gaussian beam at a source-to-target distance of 185 cm and waist of 1.5 mm was determined to best match the incident field of the experimental apparatus. A photograph of the CASI is shown in Fig. 5. The operating wavelength for the measurements and simulations was 3.39 μm.

Fig. 5

The experimental setup for the Schmitt Measurement Services CASI. The white ray, from the lower right, represents the laser beam path incident on the white sample (laser sources not shown). The detector, positioned on a motorized rotating arm, is located at the end of the white ray leaving the sample. Any incident and observation geometry is possible by rotating the sample (either in azimuth or elevation) in combination with the detector.

The CASI incident beam spot size on the samples underfilled the field of view of its detector. Hence, one would expect to observe a large number of speckles at the detector. To handle this, the CASI uses an integrating lens that effectively averages over the received speckle pattern. This was realized in simulation by assuming that the spatial averaging over one speckle pattern performed by the CASI was equivalent to averaging over the speckle patterns predicted from numerous statistically identical rough-surface realizations (i.e., “spatial ergodicity”).³¹ For the simulation statistics to converge to within 0.1%, 400 surface realizations were required and used. Figure 6 shows the average scattered irradiances, or $\langle E_z^s({\theta }^i|{\theta }^r)E_z^{s*}({\theta }^i|{\theta }^r)\rangle$, and the measured scattered powers from the LabSphere Infragold sample versus the observation angle ${\theta }^r$ for incident angles ${\theta }^i=20 \text{deg}$, 40 deg, and 60 deg, respectively. Both the simulated (solid black traces) and measured (solid gray traces) results are shown on the same plots, but with different scales. The simulated results trend well with the measured data, with specular peaks in the same location and with roughly the same width. It should be noted that the CASI measures the scattered power from a 2-D surface, whereas the simulation predicts the scattered power from a 1-D surface. In similar previous work, Knotts et al.³² suggested that the difference between the measured and simulated data can be attributed to higher-order statistics of the rough surface that are not accurately modeled in simulation. Despite these differences, the simulated and measured results compare quite well.

Fig. 6

Average scattered irradiance and measured scattered power versus observation angle ${\theta }^r$ for the LabSphere Infragold sample. The average scattered irradiance was calculated by averaging the scattered irradiance, predicted using the MoM, over 400 independent surface realizations generated using the LabSphere Infragold’s measured roughness statistics. The scattered power measurements were taken using the CASI. The angles of incidence are (a) 20 deg, (b) 40 deg, and (c) 60 deg.

4.2.

Validation of the GSM Form for Surfaces with Gaussian Height Distributions and Gaussian Autocorrelation Functions Illuminated at Normal Incidence

Earlier studies¹¹ have shown that if a rough surface with Gaussian statistics is illuminated at normal incidence, the scattered field autocorrelation function follows a GSM form. This implies the average scattered irradiance and the normalized autocorrelation function are both Gaussian and separable. Further, the normalized autocorrelation function depend on the difference of observation angles. In order to validate this, MoM simulations were performed for very rough and smooth-to-moderately rough surfaces.

4.2.1.

Very rough surfaces

For these simulations, 1000 independent realizations of a rough surface following Gaussian statistics were generated. The surface height standard deviation and correlation length for these simulated surfaces were 11 and 117 μm, respectively, corresponding to the measured statistics of the LabSphere Infragold target. The operating wavelength was, again, 3.39 μm. Figure 7(a) shows the average far-field scattered irradiance for normal incidence as the observation angle is varied from $-90\mathrm{deg}$ to 90 deg. The average scattered irradiance is very near Gaussian. Figure 7(b) and 7(c) shows the normalized autocorrelation functions calculated around 0 deg (normal) and 30 deg observation directions, respectively. The normalized autocorrelation function of the scattered field is calculated as

Eq. (16)

$$\mu ({\theta }^r,{\theta }^r+\mathrm{\Delta }{\theta }^r)=\frac{|\langle E_z^s({\theta }^r)E_z^{s*}({\theta }^r+\mathrm{\Delta }{\theta }^r)\rangle |}{\sqrt{\langle E_z^s({\theta }^r)E_z^{s*}({\theta }^r)\rangle }\sqrt{\langle E_z^s({\theta }^r+\mathrm{\Delta }{\theta }^r)E_z^{s*}({\theta }^r+\mathrm{\Delta }{\theta }^r)\rangle }},$$

where the functional dependence on ${\theta }^i$ has been omitted for convenience. Like the average scattered irradiance, the normalized autocorrelation functions are very near Gaussian; however, the two functions have different widths, suggesting that $\mu$ is not a function of $\mathrm{\Delta }{\theta }^r$ alone. Note that the scattered field is correlated for small $\mathrm{\Delta }{\theta }^r$. An analytical model based on the physical-optics approximation developed by Hyde et al.³³ shows that $\mu$ depends on the difference of the projected angles $\sin {\theta }_1^r$ and $\sin {\theta }_2^r$. Further, since the scattered field is correlated over small angular separations, it was shown that the normalized autocorrelation function can be approximated as a function of only $\mathrm{\Delta }{\theta }^r$ by dividing it by $\cos {\theta }^r$. This finding verifies the work of Korotkova et al.,¹¹ whose analysis, restricted to the paraxial regime, showed that $\mu$ depended on the difference of observation-plane coordinates. Nevertheless, since $\mu$ is not a function of $\mathrm{\Delta }{\theta }^r$ alone, the scattered field autocorrelation function does not adhere to the GSM definition in general. Note that the widths of the normalized autocorrelation functions are on the order of $\lambda /D$, where $\lambda$ is the wavelength and $D$ is the spot size on the target. This is consistent with earlier theories developed by Goodman¹² and Korotkova et al.¹¹

Fig. 7

Average far-field scattered irradiance and normalized autocorrelation functions at normal incidence for a simulated rough Gaussian surface with a height standard deviation of 11 μm and correlation length of 117 μm. (a) Average scattered irradiance; (b) and (c) are the normalized autocorrelation function plots for observation at 0 deg and 30 deg, respectively. The scattered irradiance profile and the normalized autocorrelation function plots have a distinctive Gaussian shape. Note that the widths of the traces in (b) and (c) are different, suggesting that $\mu$ is not a function of $\mathrm{\Delta }{\theta }^r$ alone.

4.2.2.

Smooth to moderately rough surfaces

The normalized autocorrelation function can no longer be described by a Gaussian function as the surface gets smoother with respect to wavelength. This behavior was noted by Goodman for near-field scattering observed just above the rough surface.³⁴ Figure 8 shows the normalized autocorrelation functions for observation around the specular direction for a Gaussian surface at normal incidence when the surface height standard deviation is varied. The correlation lengths of the simulated surfaces were $8\lambda$. When the surface roughness is much smaller than the wavelength (i.e., ${\sigma }_h=0.05\lambda$ and $0.1\lambda$), the normalized autocorrelation functions are marked by non-Gaussian shapes and approach an asymptotic value for large separation angles. This behavior at large separation angles is due to a nonzero mean scattered field $\langle E_z^s({\theta }^i|{\theta }^r)\rangle$ and physically denotes the existence of a strong specular component in the scattered wave.³⁴ As the surface roughness increases to $0.25\lambda$, the normalized autocorrelation function starts assuming a Gaussian shape and the horizontal asymptote disappears, implying that the mean scattered field is zero, as in the very rough surface analysis discussed previously.

Fig. 8

Normalized autocorrelation functions of the far-zone scattered-field at normal incidence and normal observation for simulated rough Gaussian surfaces as surface roughness is varied. For ${\sigma }_h=0.05\lambda$ and ${\sigma }_h=0.1\lambda$, the normalized autocorrelation functions are non-Gaussian and approach an asymptotic value for large separation angles. The normalized autocorrelation function is very nearly Gaussian for ${\sigma }_h=0.25\lambda$.

4.3.

Validation of GSM Form for Scattering from Sample Targets

For these simulations, the MoM was used to predict the scattered radiation in the far field for 400 independent surface realizations using the measured statistics of LabSphere Infragold and sandblasted steel. Incident angles of 20 deg, 40 deg, and 60 deg were used in the simulations. Figure 9 shows the far-field average scattered irradiances for both samples for different angles of incidence. Similarities are observed in the scattering from both samples. The scattering is maximum in the specular direction even at ${\theta }^i=60\mathrm{deg}$. Masking, shadowing, and multiple scattering effects do not appear to be significant in either target. The statistical analysis of the profilometer measurements suggested that both LabSphere Infragold and sandblasted steel had surface height distributions and correlation functions that were non-Gaussian. Figure 9 suggests that the non-Gaussian nature of the surfaces makes the angular scattered irradiance also non-Gaussian. This non-Gaussian behavior is more apparent at higher angles of incidence.

Fig. 9

Average scattered irradiances for LabSphere Infragold and sandblasted steel. Angles of incidence are (a) 20 deg, (b) 40 deg, and (c) 60 deg.

The behavior of the normalized autocorrelation functions was also examined using the simulated data. The normalized autocorrelation functions for an incident angle of 20 deg and different observation directions are shown in Fig. 10. The normalized autocorrelation functions have Gaussian shapes, but the angular widths of the functions are different, suggesting the same behavior of $\mu$ that was observed earlier in Sec. 4.2.1. Figure 11 shows the normalized autocorrelation functions for both samples in the specular direction for three different angles of incidence. It is evident from the plots that the angular width of the normalized autocorrelation function for observation near the specular angle (being nearly the same in all three plots) is independent of incident direction. This finding is consistent with Goodman’s classic result.¹² Note that the width of the normalized autocorrelation function physically denotes the average angular extent of a speckle.

Fig. 10

Normalized autocorrelation functions of the far-zone scattered field of LabSphere Infragold and sandblasted steel in different observation directions. In all the plots, the angle of incidence is 20 deg. The observation directions are (a) 0 deg (normal), (b) 20 deg (specular), and (c) 40 deg. The normalized autocorrelation functions are nearly Gaussian, with very similar angular widths for both samples. Note that the angular widths are different depending on the observation direction.

Fig. 11

Normalized autocorrelation functions of the far-zone scattered field of LabSphere Infragold and sandblasted steel when observation is in the specular direction. The angles of incidence are (a) 20 deg, (b) 40 deg, and (c) 60 deg. The angular widths for all three cases are nearly identical.