1. Introduction

Underground mining (UM) is considered a sector in which worker health is at high risk [1]. In an underground mine, miners are constantly exposed to a harsh work environment with unique characteristics such as high humidity, temperature, hazardous gas and dust concentrations, and noise, as well as poor visibility [2]. These factors negatively impact miners’ mental and physical health in the long term, in addition to the fact that the work scenario is subject to unpredictable hazards such as fires, explosions, roof collapses, earthquakes, toxic gas leaks, floods, and vehicle accidents that could cause serious injuries or disabilities, and in the worst cases, fatalities [3]. Reliable wireless communication systems play a significant role in maintaining miners’ safety. Applications such as mobile two-way voice communications and tracking miners’ locations are crucial in an emergency, while monitoring systems for air quantity and hazardous gas and dust concentration ensure worker safety throughout the mine operation [4].

As the most widely used type of wireless communication, radio frequency (RF) communications suffer from severe electromagnetic interference (EMI): equipment used during normal mining operations such as drill machines, mine trucks, electric motors, and continuous miners operate in the same frequency range as radio communication devices, causing a significant amount of noise [4]. To complement the classical wireless communication systems deployed in UM, researchers have proposed the use of visible light communications (VLC), in which a light-emitting diode (LED) is intensity-modulated by a driving current at the transmitter (TX), producing a visible light signal that is detected by a photodiode (PD) that produces a photocurrent at the receiver (RX). The optical signal is modulated rapidly enough to be not perceived by the human eye, making VLC systems suitable for data transmission and illumination at the same time. Its immunity to EMI, relatively low cost, unlicensed frequency spectrum, support of high data rates, and the fact that underground mines already depend on artificial light sources for their functioning make VLC an attractive candidate for short-range wireless communications in underground mines [5,6].

Although the VLC channel for classical indoor environments (i.e., regular buildings) has been studied well, the underground mining VLC channel (UM-VLC) has only recently been a topic of research interest. Over the past few years, several authors have proposed UM-VLC channel models that account for channel characteristics inherent to the UM environment that are not present in classical indoor environments. These include, but are not limited, to the relative tilt and rotation between LED and PD, irregular (i.e., non-flat) walls, light scattering and absorption due to dust, and shadowing (e.g., large machinery blocking the light signal) [7,8]. However, to the best of the authors’ knowledge, no UM-VLC channel model has been proposed in the literature that accounts for the wavelength’s dependence of the aforementioned phenomena or the inherent spectral properties of LEDs and PDs. Although VLC channel models that do not account for wavelength dependency are suitable for VLC systems with monochromatic or narrowband light sources, illumination systems require white-light LEDs that are inherently wideband. Miramirkhani and Uysal [9] argue that the wideband property of white light LEDs calls for the inclusion of wavelength dependency in VLC channel modeling and proceed to mention multiple research papers that propose wavelength-dependent classical in-door VLC channels.

Furthermore, wavelength dependency becomes an even more important factor when considering color-domain-based VLC systems, in which the wavelength dependence of the channel is crucial to the system’s performance. The most notable color-domain-based modulation scheme is known as color shift keying (CSK) modulation, in which data are encoded into the instantaneous optical power of RGB LEDs in such a way that the perceived color and the average transmitted optical are static [10]. This modulation scheme is included in the IEEE 802.15.7 standard [11] for high-data-rate applications with multiple light sources, where 4-CSK, 8-CSK, and 16-CSK constellations are defined. Most of the existing literature on the performance and channel modeling of CSK-based VLC systems considers classical indoor VLC channels with only a line-of-sight (LOS) component. Notable exceptions include the outdoor optical camera communications channel (OOC) [12], the underwater optical communication channel (UWOOC) [13], and the underwater wireless optical communication channel (UWOC) [14]. To the best knowledge of the authors, CSK-based UM-VLC systems have not been modeled or evaluated in the literature so far.

In this work, we propose a wavelength-dependent UM-VLC single-input, single-output (SISO) channel model in which the spectral characteristics of the LED, the PD, the dust particles, and the reflective surfaces are considered. The UM-VLC channel model based on ray tracing proposed by Palacios et al. [7] is used as a starting point, from which the LED/PD tilt and rotation model, the shadowing model, and the irregular wall model are inherited. Additionally, we include a dust scattering and absorption model based on Mie theory, which has already been considered in state-of-the-art UM-VLC channel models such as the one presented by Javaid et al. [5], although without considering its spectral characteristics.

The proposed wavelength-dependent UM-VLC channel model allows us to define a CSK-based UM-VLC channel model very naturally. A simulation scenario with appropriate parameters is implemented to evaluate the CSK-based UM-VLC system in terms of the average received optical power, the signal-to-interference ratio (SIR), the signal-to-noise ratio (SNR), the channel impulse response (CIR), the root mean square (RMS) delay, and the bit error rate (BER). With these metrics, the performance of the CSK-based UM-VLC system was compared with the performance achieved under the reference channel proposed by [7].

The contributions of this paper can be summarized as follows:

• A novel wavelength-dependent SISO UM-VLC channel model is proposed, taking into account LED/PD relative tilt and rotation, irregular walls, shadowing, light scattering, absorption, and their respective spectral characteristics. The LED is modeled as a Lambertian light source and the ray tracing method is used.

• A novel wavelength-dependent CSK-based UM-VLC channel model is proposed on the basis of the proposed wavelength-dependent SISO UM-VLC channel model.

• The performance of the proposed CSK-based UM-VLC channel model is evaluated in a simulated environment, obtaining parameters such as the average received optical power, SIR, SNR, CIR, RMS delay, and BER. The proposed model is then compared to a reference state-of-the-art UM-VLC channel model.

The paper is structured as follows: Section 1 presents a brief introduction and gives a review of the various UM-VLC channel models presented in the literature. Section 2 defines important concepts in the topics of VLC and CSK necessary for contextualizing the rest of the text, while also defining the UM-VLC channel model proposed in this paper. Section 3 presents the simulation results and discusses them. Finally, the conclusions are provided in Section 4.

Related Work

Due to the relative hostility of mines compared to classical indoor environments, various channel models have been proposed for UM-VLC systems. In Ref. [15], the authors propose a geometric-based deterministic model (GBDM) considering the LOS and NLOS components for a coal mine’s workface with hydraulic support metal columns along its footpath. The authors considered the reflections of the metal columns, roof, and floor. Additionally, they also derive the optimal TX location that maximizes the coupled energy of the light signals blocked by the metal columns. The authors also studied the degrading effect of coal dust on the optical signal, employing Mie theory for modeling light scattering and absorption.

The authors of [16] have proposed a recursive UM-VLC channel model that considers light scattering and absorption due to particles and shadowing caused by people. They simulate both a mining roadway and a workface scenario containing multiple transmitters modeled as ideal Lambertian sources and obtain the path loss and RMS delay for the LOS and NLOS links, considering multiple link ranges. Mie theory is used to model light attenuation caused by dust, and a bimodal Gaussian distribution (BGD) is used to model shadowing phenomena.

In Ref. [17], the authors present a VLC channel model for underground tunnels in general. They focus their attention on the relative orientation of LEDs and PDs and their effect on the irradiance and incidence angles, proposing a Lambertian VLC channel model that considers an LOS component dependent on the azimuthal (tilt) and polar (rotation) angles of LEDs and PDs and a diffuse NLOS component independent of the PD’s incident angle. They provide simulation results in a tunnel scenario in terms of the symbol error rate (SER) for a VLC link based on pulse amplitude modulation (PAM).

In Refs. [7,18,19], the authors propose a ray-tracing-based UM-VLC channel considering a Lambertian light source, arbitrary LED and PD tilt and rotation angles, reflections on non-flat irregular walls, scattering due to dust particles, and shadowing due to large machinery. The LED/PD tilt and rotation modeling is taken from [17]. The irregularity of the walls is modeled by discretizing the walls into a grid with small wall segments, each with nondeterministic azimuthal and polar angles. The shadowing effect is modeled as a weighting parameter in the LOS and NLOS links and is calculated as the expected value of a Poisson process which describes the random entry of light-blocking objects into the simulation scenario. The light scattering is modeled as a combination of Rayleigh and Mie regimes, with dust particles randomly distributed around the PD in a two-dimensional disk in [7] and in a hemispheric three-dimensional region in [18]. The light-degrading effects of scattering are not factored into the LOS and reflection-induced NLOS links; instead, another NLOS channel link is modeled, induced by the scattered light, in what could be called a scattering-induced NLOS link. Scattering-induced NLOS links are common in optical communication channels where TX and RX are blocked by obstacles or the LOS link cannot be guaranteed [20], whereas it is not common in VLC channels since the LOS link is usually available. In Ref. [7], the proposed channel model was evaluated in a simulated UM tunnel. The resulting CIR, received optical power, and RMS delay were presented and compared with a referential classical indoor VLC channel model. In Ref. [18], the same simulated environment was used, with CIR, received optical power, SNR, RMS delay, and BER being presented for different amounts of modeled dust particles, and compared to the proposed channel model in [7], considering on–off keying (OOK) modulation.

In Ref. [5], the authors propose a UM-VLC channel based on ray tracing for coal mines, considering a Lambertian light source, scattering, and absorption of light and shadowing. Mie theory is used to model the scattering and absorption due to coal dust, while shadowing is modeled using a BGD. Simulations are performed in a mine gallery and sub-gallery where the resulting path loss, received power, RMS delay, SNR, and probability of error are presented and analyzed as a function of link distance. The CIR is also presented for the two simulation scenarios.

In Table 1, the aforementioned UM-VLC channel models are compared in terms of how many UM-related factors they consider. It is clear that there is a gap in the study of wavelength dependence in the context of UM-VLC channels that this present paper seeks to remediate. Wavelength-dependent channels have been proposed in all kinds of optical communication systems. For instance, wavelength-dependent optical channels have been proposed for classical indoor VLCs in empty rooms [21] and in rooms with objects [22] and for UWOC [23], to name a few.

2. Materials and Methods

2.1. General VLC Link

Given a monochromatic LED producing an optical power signal $x\left(t\right)$, the photocurrent $y\left(t\right)$ detected at the PD is given by

(1)$y\left(t\right)=Rh\left(t\right)\ast x\left(t\right)+n\left(t\right),$

(2)$x\left(t\right)\ge 0,\forall t.$

Furthermore, the illumination requirement implies that the average transmitted optical power must remain at a constant optical power $P_{\mathrm{avg}}$, given by [24]

(3)$P_{\mathrm{avg}}=\underset{T\to \infty }{lim}\frac{1}{2T}{\int }_{-T}^{T}x\left(t\right)dt.$

The optical signal is also bounded by the optical power produced by the LED at the peak drive current, $P_{\mathrm{peak}}$, i.e.,

(4)$x\left(t\right)\le P_{\mathrm{peak}},\forall t.$

An important element of the VLC channel model is the optical DC gain, $H\left(0\right)$, given by

(5)$H\left(0\right)={\int }_0^{\infty }h\left(t\right)dt.$

Equivalently, the electro-optical DC gain is given by $RH\left(0\right)$. Modeling the channel DC gain is desired because it allows us to obtain the received optical power $P_R$ and produced photocurrent $I_{\mathrm{ph}}$ at the PD for a given transmitted optical power $P_T$ by [25]

(6)$P_R=H\left(0\right)P_T\mathrm{and}{I}_{\mathrm{ph}}=RH\left(0\right)P_T.$

2.2. CSK Modulation

Color-shift keying is a VLC modulation scheme involving multiple LEDs, in which the average emitted optical color and the total optical power are kept constant. It is included in the IEEE 802.15.7 standard for short-range optical wireless communications as part of the PHY III mode of the VLC physical layer, which is used for high-data-rate applications in indoor environments [11].

A CSK-based system consists of three RGB LEDs, each transmitting a primary color, red, green, or blue, and three PDs with optical filters that let through one of the primary colors each. CSK symbols are defined in the CIE 1931 $xy$ color space. The center-of-band wavelengths of the three LEDs ${\lambda }_r$, ${\lambda }_g$, ${\lambda }_b$ are expressed in CIE 1931 $xy$ space coordinates by

(7)${\mathbf{s}}_r=\left[\begin{array}{c}{x}_r\\ y_r\end{array}\right],{\mathbf{s}}_g=\left[\begin{array}{c}{x}_g\\ y_g\end{array}\right],{\mathbf{s}}_b=\left[\begin{array}{c}{x}_b\\ y_b\end{array}\right],$

(8)$G=\{{\alpha }_1{\mathbf{s}}_r+{\alpha }_2{\mathbf{s}}_g+{\alpha }_3{\mathbf{s}}_b\in {\mathbb{R}}^2\mid {\alpha }_1+{\alpha }_2+{\alpha }_3=1,{\alpha }_1,{\alpha }_2,{\alpha }_3\ge 0\},$

(9)${\mathbf{s}}_n=\left[\begin{array}{c}{x}_n\\ y_n\end{array}\right]\in G,\forall n=1,\cdots ,M.$

In theory, an infinite number of gamuts and constellations can be defined in the system. However, the IEEE 802.15.7 standard considers only fourteen possible system gamuts and establishes a set of rules to construct symbol constellations given the number of symbols M and the system gamut G. The ruleset for constellation construction is laid out in [11]. All possible gamuts and system constellations for 4-CSK, 8-CSK, and 16-CSK, together with their corresponding data mapping, as defined by the IEEE 802.15.7 standard, are presented in [26].

Consider a CSK RGB luminary whose average transmitted optical power must not exceed $P_{\mathrm{avg}}$. In order to transmit symbol ${\mathbf{s}}_n={[x_n,y_n]}^{\mathrm{T}}\in G$, it must be converted into an optical power triplet ${[P_{1,n},P_{2,n},P_{3,n}]}^{\mathrm{T}}$ such that

(10)$P_{1,n}+P_{2,n}+P_{3,n}=P_{\mathrm{avg}}$

(11)$\begin{array}{c}\hfill \begin{array}{cc}\hfill x_n& ={\overline{P}}_1{x}_r+{\overline{P}}_2{x}_g+{\overline{P}}_3{x}_b\hfill \\ \hfill y_n& ={\overline{P}}_1{y}_r+{\overline{P}}_2{y}_g+{\overline{P}}_3{y}_b\hfill \\ \hfill 1& ={\overline{P}}_1+{\overline{P}}_2+{\overline{P}}_3.\hfill \end{array}\end{array}$

Consider ${\overline{P}}_{1,n},{\overline{P}}_{2,n},$ and ${\overline{P}}_{3,n}$ to be the solution to Equation (11). Then, the desired optical power triplet for symbol ${\mathbf{s}}_n$ is given by

(12)$\left[\begin{array}{c}{P}_{1,n}\\ P_{2,n}\\ P_{3,n}\end{array}\right]=P_{\mathrm{avg}}\left[\begin{array}{c}{\overline{P}}_{1,n}\\ {\overline{P}}_{2,n}\\ {\overline{P}}_{3,n}\end{array}\right].$

This also implies that the possible optical power values emitted by the LEDs are bounded by $P_{\mathrm{avg}}$, i.e.,

(13)$0\le P_{1,n}\le P_{\mathrm{avg}},0\le P_{2,n}\le P_{\mathrm{avg}},0\le P_{3,n}\le P_{\mathrm{avg}},\forall n=1,\cdots ,M.$

Additionally, in all CSK constellations allowed by the IEEE 802.15.7 standard, the optical power transmitted by each LED averaged over all possible symbols is given by [27]

(14)$\frac{1}{M}\sum _{n=1}^M{P}_{1,n}=\frac{1}{M}\sum _{n=1}^M{P}_{2,n}=\frac{1}{M}\sum _{n=1}^M{P}_{3,n}=\frac{P_{\mathrm{avg}}}{3}.$

Given a CSK optical power signal $\mathbf{x}\left(t\right)={[x_1\left(t\right),x_2\left(t\right),x_3\left(t\right)]}^{\mathrm{T}}$ (W) as input, where $x_1\left(t\right)$, $x_2\left(t\right)$, $x_3\left(t\right)$ represent the instantaneous emitted power from the red, green, and blue LED, respectively, we can calculate the instantaneous photocurrent signal $\mathbf{y}\left(t\right)={[y_1\left(t\right),y_2\left(t\right),y_3\left(t\right)]}^{\mathrm{T}}$ (A), where $y_1\left(t\right)$, $y_2\left(t\right)$, and $y_3\left(t\right)$ represent the instantaneous photocurrent produced at the red, green, and blue PD, respectively, by

(15)$y_j\left(t\right)=\sum _{i=1}^{3}h[i,j]\left(t\right)\ast x_i\left(t\right)+n_j\left(t\right),i,j=1,2,3,$

(16)$P_{\mathrm{avg},i}=\underset{T\to \infty }{lim}\frac{1}{2T}{\int }_{-T}^T{x}_i\left(t\right)dt.$

From Equation (14), it follows that

(17)$P_{\mathrm{avg},1}=P_{\mathrm{avg},2}=P_{\mathrm{avg},3}=\frac{P_{\mathrm{avg}}}{3},$

(18)$P_{\mathrm{avg}}=\underset{T\to \infty }{lim}\frac{1}{2T}{\int }_{-T}^T\sum _{i=1}^3{x}_i\left(t\right)dt.$

In high-speed VLC schemes, such as CSK-based VLC systems, the impulse response of the LED must be considered [25]. By denoting the impulse response of the LEDs as $h_{\mathrm{LED}}\left(t\right)$, Equation (15) can be rewritten as

(19)$y_j\left(t\right)=\sum _{i=1}^3{h}_{\mathrm{LED}}\left(t\right)\ast h[i,j]\left(t\right)\ast x_i\left(t\right)+n_j\left(t\right),$

(20)$H_0^{\mathrm{el}}[i,j]={\int }_0^{\infty }h[i,j]\left(t\right)dt.$

In this context, we can define the average photocurrent produced at the jth PD due to light coming from the ith LED, $I_{\mathrm{avg}}[i,j]$, as

(21)$I_{\mathrm{avg}}[i,j]=H_0^{\mathrm{el}}[i,j]·P_{\mathrm{avg},i}.$

In the VLC literature, additive noise is usually decomposed into the two dominant sources of noise in the VLC link: thermal noise and shot noise. The former, also known as Johnson–Nyquist noise, accounts for the thermal fluctuation (i.e., the temperature) in the particles that constitute the receiver electronics. The later accounts for the noise caused by the fluctuation in the number of photons that hit the jth PD within a certain time unit. Thermal noise is modeled as additive white Gaussian noise (AWGN), since it is the result of many independent events (thermal fluctiation of individual electrons). Similarly, shot noise is well approximated by AWGN thanks to the central limit theorem, as it is the superposition of a large number of independent events (photons hitting the PD at different times) [28]. With this in mind, and considering that thermal noise and shot noise are statistically independent, the noise variance can be further decomposed as follows:

(22)${\sigma }_j^2={\sigma }_{\mathrm{shot},j}^2+{\sigma }_{\mathrm{thermal}}^2,$

(23)${\sigma }_{\mathrm{shot},j}^2=2qB\sum _{i=1}^3{I}_{\mathrm{avg}}[i,j]+2q{I}_{\mathrm{bg}}{I}_{2}B,$

(24)${\sigma }_{\mathrm{thermal}}^2=\frac{8\pi \kappa T_k}{G_{\mathrm{ol}}}{C}_{\mathrm{pd}}{A}_R{I}_2{B}^2+\frac{16{\pi }^2\kappa T_k\mathsf{\Gamma }}{g_m}{C}_{\mathrm{pd}}^2{A}_R^2{I}_3{B}^3,$

Assuming that the additive noise is AWGN, then the electrical SNR for the jth PD, ${\mathrm{SNR}}_{\mathrm{el},j}$, is given by [24]

(25)${\mathrm{SNR}}_{\mathrm{el},j}=\frac{{\left(I_{\mathrm{avg}}[j,j]\right)}^2}{{\sigma }_j^2}.$

The electrical signal-to-interference ratio (SIR) for the jth PD, ${\mathrm{SIR}}_{\mathrm{el},j}$, is given by

(26)${\mathrm{SIR}}_{\mathrm{el},j}=\frac{{\left(I_{\mathrm{avg}}[j,j]\right)}^2}{{\sum }_{i\ne j}{\left(I_{\mathrm{avg}}[i,j]\right)}^2},$

2.3. Reference UM-VLC Channel Model

The UM-VLC SISO channel model proposed in [7] is used as the reference channel. This channel model considers a monochromatic LED as a generalized Lambertian light source, a PD pair rotated and titled to each other, irregular walls (i.e., non-flat), shadowing, and a scattering component. Taking into account an optical input and an optical output, the DC gain of the channel model is given by

(27)$H_{\mathrm{ref},}\mathrm{opt}=H_{\mathrm{LOS}}+H_{\mathrm{NLOS},\left(1\right)}+H_{\mathrm{scatter}},$

(28)$H_{\mathrm{ref},}\mathrm{el}=R(H_{\mathrm{LOS}}+H_{\mathrm{NLOS},\left(1\right)}+H_{\mathrm{scatter}}).$

Figure 1 presents an illustration of the reference channel model and serves as a companion to the following sections.

2.3.1. Geometry

Before defining the channel components, it is convenient to define some geometrical parameters. Let us consider an underground tunnel of dimensions $L_x\times L_y\times L_z$ (m), corresponding to its length (x-axis), width (y-axis), and height (z-axis), respectively. The TX or LED is positioned in the fixed coordinates $\mathbf{T}={[x_{\mathrm{tx}},y_{\mathrm{tx}},z_{\mathrm{tx}}]}^{\mathrm{T}}$ (m), whereas the receiver position (RX) or the PD position, $\mathbf{R}={[x_{\mathrm{rx}},y_{\mathrm{rx}},z_{\mathrm{rx}}]}^{\mathrm{T}}$ (m), can vary. Having defined these parameters, the distance between the LOS links, d, is given by

(29)$d=\left|\right|\mathbf{R}-\mathbf{T}\left|\right|.$

Consider ${\mathbf{n}}_{\mathrm{tx}}={[n_{\mathrm{tx}}^x,n_{\mathrm{tx}}^y,n_{\mathrm{tx}}^z]}^{\mathrm{T}}$ as the TX normal vector and ${\mathbf{n}}_{\mathrm{rx}}={[n_{\mathrm{rx}}^x,n_{\mathrm{rx}}^y,n_{\mathrm{rx}}^z]}^{\mathrm{T}}$ as the RX normal vector. Using the same definitions as [7], the RX tilt angle, ${\beta }_{\mathrm{rx}}$, is defined as the angle from the z-axis vector, ${[0,0,1]}^{\mathrm{T}}$ to ${\mathbf{n}}_{\mathrm{rx}}$, whereas the TX tilt angle, ${\beta }_{\mathrm{tx}}$, is defined as the angle from the negative z-axis vector, ${[0,0,-1]}^{\mathrm{T}}$ to ${\mathbf{n}}_{\mathrm{tx}}$. Both tilt angles’ definitions are illustrated in Figure 1b. Assuming that TX is higher on the z-axis than RX, then we want the tilt angles to have values ${\beta }_{\mathrm{tx}},{\beta }_{\mathrm{rx}}\in [0,\frac{\pi }{2}]$.

We denote ${\mathbf{n}}_{\mathrm{tx}}^{\mathrm{proj},z}={[n_{\mathrm{tx}}^x,n_{\mathrm{tx}}^y,0]}^{\mathrm{T}}$ as the projection of ${\mathbf{n}}_{\mathrm{tx}}$ onto the x–y plane and ${\mathbf{n}}_{\mathrm{rx}}^{\mathrm{proj},z}={[n_{\mathrm{rx}}^x,n_{\mathrm{rx}}^y,0]}^{\mathrm{T}}$ as the projection of ${\mathbf{n}}_{\mathrm{rx}}$ onto the x–y plane. Using the same definitions as [7], the RX rotation angle, ${\alpha }_{\mathrm{rx}}$, is defined as the angle from the x-axis vector, ${[1,0,0]}^{\mathrm{T}}$ to ${\mathbf{n}}_{\mathrm{rx}}^{\mathrm{proj},z}$, whereas the TX rotation angle, ${\alpha }_{\mathrm{tx}}$, is defined as the angle from the x-axis vector, ${[1,0,0]}^{\mathrm{T}}$ to ${\mathbf{n}}_{\mathrm{tx}}^{\mathrm{proj},z}$. The definitions of both rotation angles are illustrated in Figure 1c. A priori, there are no restrictions on the rotation angle values, i.e., ${\alpha }_{\mathrm{tx}},{\alpha }_{\mathrm{rx}}\in [0,2\pi )$.

With these definitions, we can express ${\mathbf{n}}_{\mathrm{tx}}$ and ${\mathbf{n}}_{\mathrm{rx}}$ by [7]

(30)${\mathbf{n}}_{\mathrm{tx}}=\left[\begin{array}{c}sin\left({\beta }_{\mathrm{tx}}\right)cos\left({\alpha }_{\mathrm{tx}}\right)\\ sin\left({\beta }_{\mathrm{tx}}\right)cos\left({\alpha }_{\mathrm{tx}}\right)\\ -cos\left({\beta }_{\mathrm{tx}}\right)\end{array}\right]\mathrm{and}{\mathbf{n}}_{\mathrm{rx}}=\left[\begin{array}{c}sin\left({\beta }_{\mathrm{rx}}\right)cos\left({\alpha }_{\mathrm{rx}}\right)\\ sin\left({\beta }_{\mathrm{rx}}\right)cos\left({\alpha }_{\mathrm{rx}}\right)\\ cos\left({\beta }_{\mathrm{rx}}\right)\end{array}\right].$

2.3.2. Reference LOS Link

The LOS component $H_{\mathrm{LOS}}$ can be further expressed as [7]

(31)$H_{\mathrm{LOS}}=\mathcal{C}\mathcal{G}\frac{(m+1)A_R}{2\pi d^2}{\mathsf{\Omega }}_{\mathrm{LOS}}{\mathsf{\Psi }}_{\mathrm{LOS}},$

(32)${\theta }_0=arccos\left(\frac{1}{d}{(\mathbf{T}-\mathbf{R})}^{\mathrm{T}}{\mathbf{n}}_{\mathrm{rx}}\right).$

Therefore, $\mathcal{C}$ can be expressed as

(33)$\mathcal{C}=\left\{\begin{array}{cc}\frac{\eta }{{sin}^2\left({\mathsf{\Theta }}_{\mathrm{FoV}}\right)}\hfill & 0\le {\theta }_0\le {\mathsf{\Theta }}_{\mathrm{FoV}}\hfill \\ 0\hfill & {\theta }_0>{\mathsf{\Theta }}_{\mathrm{FoV}},\hfill \end{array}\right.$

(34)${\mathsf{\Omega }}_{\mathrm{LOS}}=\left(\frac{1}{d}{(\mathbf{T}-\mathbf{R})}^{\mathrm{T}}{\mathbf{n}}_{\mathrm{rx}}\right)\times {\left(\frac{1}{d}{(\mathbf{R}-\mathbf{T})}^{\mathrm{T}}{\mathbf{n}}_{\mathrm{tx}}\right)}^m.$

2.3.3. Reference NLOS Link

The single-hop NLOS component $H_{\mathrm{NLOS},\left(1\right)}$ can be further expressed as [7]

(35)$H_{\mathrm{NLOS},\left(1\right)}=\frac{(m+1)A_R}{2\pi }\sum _{w=1}^W{\mathcal{C}}_w{\mathcal{G}}_w\frac{A_{\mathrm{refl},w}{\rho }_w}{d_{1,w}^2{d}_{2,w}^2}{\mathsf{\Omega }}_{\mathrm{NLOS}}^{\left(w\right)}{\mathsf{\Psi }}_{\mathrm{NLOS}}^{\left(w\right)},$

Consider that the wth reflector is modeled as a VLS with position ${\mathbf{R}}_w={[x_w,y_w,z_w]}^{\mathrm{T}}$. With this, the distance between TX and the wth reflector, $d_{1,w}$, is given by

(36)$d_{1,w}=\left|\right|{\mathbf{R}}_w-\mathbf{T}\left|\right|,$

(37)$d_{2,w}=\left|\right|{\mathbf{R}}_w-\mathbf{R}\left|\right|.$

Additionally, the wth reflector is tilted by the tilt angle ${\beta }_w\in [0,\pi ]$ and rotated by the rotation angle ${\alpha }_w\in [0,\pi ]$, defined in the same way as the tilt and rotation angles of the RX. The normal vector to the surface of the w-reflector is denoted by ${\mathbf{n}}_w={[n_w^x,n_w^y,n_w^z]}^{\mathrm{T}}$ and can be calculated with [7]

(38)${\mathbf{n}}_w=\left[\begin{array}{c}sin\left({\beta }_w\right)cos\left({\alpha }_w\right)\\ sin\left({\beta }_w\right)cos\left({\alpha }_w\right)\\ cos\left({\beta }_w\right)\end{array}\right].$

Figure 2 illustrates the tilt and rotation angle definitions. We denote by ${\theta }_w$ the incident angle at which the light coming from the wth reflector reaches the PD, and we calculate it by [7]

(39)${\theta }_w=arccos\left(\frac{1}{d_{2,w}}{({\mathbf{R}}_w-\mathbf{R})}^{\mathrm{T}}{\mathbf{n}}_{\mathrm{rx}}\right).$

Note that the dependence of ${\mathcal{C}}_w$ and ${\mathcal{G}}_w$ on the incident angle ${\theta }_w$ is implicit. Namely, ${\mathcal{C}}_w$ can be expressed as

(40)${\mathcal{C}}_w=\left\{\begin{array}{cc}\frac{\eta }{{sin}^2\left({\mathsf{\Theta }}_{\mathrm{FoV}}\right)}\hfill & 0\le {\theta }_w\le {\mathsf{\Theta }}_{\mathrm{FoV}}\hfill \\ 0\hfill & {\theta }_w>{\mathsf{\Theta }}_{\mathrm{FoV}}.\hfill \end{array}\right.$

Finally, the trigonometric parameter ${\mathsf{\Omega }}_{\mathrm{NLOS}}^{\left(w\right)}$ can be expressed as

(41)$\begin{array}{c}\hfill \begin{array}{cc}\hfill {\mathsf{\Omega }}_{\mathrm{NLOS}}^{\left(w\right)}=& \left(\frac{1}{d_{2,w}}{(\mathbf{R}-{\mathbf{R}}_w)}^{\mathrm{T}}{\mathbf{n}}_w\right)\times \left(\frac{1}{d_{2,w}}{({\mathbf{R}}_w-\mathbf{R})}^{\mathrm{T}}{\mathbf{n}}_{\mathrm{rx}}\right)\hfill \\ \hfill & \times \left(\frac{1}{d_{1,w}}{(\mathbf{T}-{\mathbf{R}}_w)}^{\mathrm{T}}{\mathbf{n}}_w\right)\times {\left(\frac{1}{d_{1,w}}{({\mathbf{R}}_w-\mathbf{T})}^{\mathrm{T}}{\mathbf{n}}_{\mathrm{tx}}\right)}^m.\hfill \end{array}\end{array}$

2.3.4. Reference Scattering Model

The NLOS scattering component $H_{\mathrm{scatter}}$ is defined in [7,18] as

(42)$H_{\mathrm{scatter}}=\underset{N\to \infty }{lim}\frac{(m+1)A_R{\rho }_s}{2N\pi }\sum _{n=1}^N\frac{p_n}{d_n^2}{\mathsf{\Omega }}_{\mathrm{scatter}}^{\left(n\right)}\mathsf{\Pi }\left({\theta }_n\right),$

(43)$\mathsf{\Pi }\left({\theta }_n\right)=\left\{\begin{array}{cc}1\hfill & 0\le {\theta }_n\le {\mathsf{\Theta }}_{\mathrm{FoV}}\hfill \\ 0\hfill & {\theta }_n>{\mathsf{\Theta }}_{\mathrm{FoV}}.\hfill \end{array}\right.$

Note that $p_n$ depends implicitly on the scattering angle ${\varphi }_n$, and can be expressed as [7,18]

(44)$p_n=\frac{k_s^{\mathrm{mie}}}{k_s}{p}_{\mathrm{mie}}\left({\varphi }_n\right)+\frac{k_s^{\mathrm{ray}}}{k_s}{p}_{\mathrm{ray}}\left({\varphi }_n\right),$

The position of the N scatterers is described by a probability distribution function. The reference channel used in this work uses a distribution contained in a two-dimensional disk around the receiver [7]. Other distributions have been proposed, such as in [18], where a distribution contained in a three-dimensional sphere around the receiver is put forward.

2.3.5. Reference Source of Reflections

In order to evaluate the reference channel, a simulation scenario is defined in [7], considering two irregular walls as the source of reflections that run the length of the tunnel. Each wall has a surface area of $L_x\times L_z$ (${\mathrm{m}}^2$) and is divided by a square grid into squares of equal area $\mathsf{\Delta }A$ (${\mathrm{m}}^2$), implying that each wall has a total of $L_x\times L_z/\mathsf{\Delta }A$ squares. $\mathsf{\Delta }A$ is a parameter that controls the resolution (hence, the accuracy) of the reflection calculation. We consider one reflector per square element of the gridded wall, with the wth having a reflective surface area of $A_{\mathrm{refl},w}$ (to not be confused with resolution area $\mathsf{\Delta }A$), position ${\mathbf{R}}_w$, rotation angle ${\alpha }_w$, and tilt angle ${\beta }_w$. With this, the total number of reflectors considered, W, is

(45)$W=2\frac{L_x{L}_z}{\mathsf{\Delta }A}.$

A common simplification is to consider the reflective area of all reflectors to be equal to a unique surface area $A_{\mathrm{refl}}$ [7], i.e.,

(46)$A_{\mathrm{refl},w}=A_{\mathrm{refl}},\forall w=1,\cdots ,W.$

In order to characterize the position ${\mathbf{R}}_w$, we can first define the set of values $x_w$, $y_w$, and $z_w$ it can take. Note that $x_w$ can take ${\ell }_x=L_x/\mathsf{\Delta }A$ values, $y_w$ can take two values (one for each wall), and $z_w$ can take ${\ell }_z=L_z/\mathsf{\Delta }A$ values, where we select $\mathsf{\Delta }A$ such that ${\ell }_x$ and ${\ell }_z$ are natural numbers. The set of possible values of $x_w$, ${\mathcal{X}}_W$, is then given by

(47)${\mathcal{X}}_W=\{x=\mathsf{\Delta }A\times n\mid n=0,1,\cdots ,{\ell }_x\},$

(48)${\mathcal{Y}}_W=\{0,L_y\}$

(49)${\mathcal{Z}}_W=\{z=\mathsf{\Delta }A\times n\mid n=0,1,\cdots ,{\ell }_z\}.$

With these definitions, the set of W possible reflector positions is given by

(50)$\{{\mathbf{R}}_1,{\mathbf{R}}_2,\cdots ,{\mathbf{R}}_W\}={\mathcal{X}}_W\times {\mathcal{Y}}_W\times {\mathcal{Z}}_W.$

To simulate diffuse reflection on irregular walls, a non-deterministic approach is employed, such that the tilt and rotation angles for the wth reflector, ${\alpha }_w$ and ${\beta }_w$, respectively, are modeled as random variables independently drawn from a uniform distribution. In general, we have for the tilt angles ${\beta }_w$ that

(51)${\beta }_w\sim \mathcal{U}[0,\pi ],\forall w=1,\dots ,W,$

(52)${\alpha }_w\sim \mathcal{U}[0,\pi ],\forall w\in \{w\mid y_w=0\},$

(53)${\alpha }_w\sim \mathcal{U}[\pi ,2\pi ],\forall w\in \{w\mid y_w=L_y\}.$

Additionally, a common simplification is that all reflectors have the same reflectance $\rho$, i.e.,

(54)${\rho }_w=\rho ,\forall w=1,\dots ,W.$

2.3.6. Reference Shadowing Model

In an LOS link with an arbitrary TX position, $\mathbf{A}=[x_a,y_a,z_a]$, and an arbitrary RX position, $\mathbf{B}=[x_b,y_b,z_b]$, the shadowing weight $\mathsf{\Psi }$, as defined in [7], is given by

(55)$\mathsf{\Psi }=exp(-ϵT_s·\mathsf{\Xi }(\mathbf{A},\mathbf{B})),$

(56)$\mathsf{\Xi }(\mathbf{A},\mathbf{B})={\int }_0^{L_y}{\int }_0^{L_x}\left({\int }_{\mathcal{F}(x,y;\mathbf{A},\mathbf{B})}^{\infty }{\int }_{2\mathcal{D}(x,y;\mathbf{A},\mathbf{B})}^{\infty }{g}_s(u,v)dudv\right)f_s(x,y)dxdy,$

(57)$\mathcal{D}(x,y;\mathbf{A},\mathbf{B})=\frac{|(y_a-y_b)x-(x_a-x_b)y-x_b{y}_a+x_a{y}_b|}{\sqrt{{(y_a-y_b)}^2+{(x_a-x_b)}^2}},$

(58)$\mathcal{F}(x,y;\mathbf{A},\mathbf{B})=\frac{{(y_a-y_b)}^2+{(x_a-x_b)}^2+{(x-x_b)}^2+{(y-y_b)}^2-{(x-x_a)}^2-{(y-y_a)}^2}{2\sqrt{{(y_a-y_b)}^2+{(x_a-x_b)}^2}}+z_b.$

With these definitions, ${\mathsf{\Psi }}_{\mathrm{LOS}}$ can be expressed as

(59)${\mathsf{\Psi }}_{\mathrm{LOS}}=exp(-ϵT_s·\mathsf{\Xi }(\mathbf{T},\mathbf{R})),$

(60)${\mathsf{\Psi }}_{\mathrm{NLOS}}^{\left(w\right)}=exp(-ϵT_s[\mathsf{\Xi }(\mathbf{T},{\mathbf{R}}_w)+\mathsf{\Xi }({\mathbf{R}}_w,\mathbf{R})]),$

2.3.7. Reference Channel Impulse Response

If we define $H_{\mathrm{NLOS},w}$ as the single-hop NLOS link formed by light reflecting off the wth reflector such that

(61)$H_{\mathrm{NLOS},\left(1\right)}=\sum _{w=1}^W{H}_{\mathrm{NLOS},w},$

(62)$H_{\mathrm{scatter}}=\sum _{n=1}^N{H}_{\mathrm{scatter},n},$

(63)$\begin{array}{c}\hfill \begin{array}{c}\hfill h_{\mathrm{ref}}\left(t\right)=R[H_{\mathrm{LOS}}·\delta \left(t-\frac{d}{c}\right)+\sum _{w=1}^W{H}_{\mathrm{NLOS},w}·\delta \left(t-\frac{d_{1,w}+d_{2,w}}{c}\right)\\ \hfill +\sum _{n=1}^N{H}_{\mathrm{scatter},n}·\delta \left(t-\frac{d_n}{c}\right)],\end{array}\end{array}$

(64)$\begin{array}{c}\hfill \begin{array}{c}\hfill h_{\mathrm{ref}}\left(t\right)=R\left[H_{\mathrm{LOS}}·\delta \left(t-\frac{d}{c}\right)+\sum _{w=1}^W{H}_{\mathrm{NLOS},w}·\delta \left(t-\frac{d_{1,w}+d_{2,w}}{c}\right)\right].\end{array}\end{array}$

2.4. Proposed UM-VLC Channel Model

The proposed channel model, not unlike the reference channel model, is a UM-VLC channel model that considers the relative rotation and tilt of the LED and the PD, irregular walls, shadowing, and scattering. The difference is that $H_{\mathrm{ref}}$ describes the channel transmission for an SISO link considering a monochromatic LED as the TX, whereas our proposed channel model takes into account a multichromatic LED and the spectral distribution of different channel parameters. Additionally, our model takes into account attenuation from light scattering and absorption caused by dust particles, which are absent from the reference model.

The DC gain of the proposed channel model for optical inputs and optical outputs takes the form

(65)$H_{\mathrm{opt}}=H_{\mathrm{LOS}}^{\mathrm{opt}}+H_{\mathrm{NLOS},\left(1\right)}^{\mathrm{opt}},$

(66)$H_{\mathrm{opt}}=\frac{P_R}{P_T},$

(67)$P_T={\int }_{380\mathrm{nm}}^{825\mathrm{nm}}\mathsf{\Phi }\left(\lambda \right)d\lambda .$

Equivalently, $P_R$ can be expressed as

(68)$P_R={\int }_{380\mathrm{nm}}^{825\mathrm{nm}}\mathcal{A}\left(\lambda \right)\mathsf{\Phi }\left(\lambda \right)d\lambda ,$

(69)$\mathcal{A}\left(\lambda \right)={\mathcal{A}}_0\left(\lambda \right)+\sum _{w=1}^W{\mathcal{A}}_w\left(\lambda \right),$

(70)$H_{\mathrm{LOS}}^{\mathrm{opt}}=\frac{1}{P_T}\int {\mathcal{A}}_0\left(\lambda \right)\mathsf{\Phi }\left(\lambda \right)d\lambda ,$

(71)$H_{\mathrm{NLOS},\left(1\right)}^{\mathrm{opt}}=\frac{1}{P_T}\sum _{w=1}^W\int {\mathcal{A}}_w\left(\lambda \right)\mathsf{\Phi }\left(\lambda \right)d\lambda ,$

Considering Equation (68) as the definition of the optical power received, the electrical photocurrent $I_{ph}$ produced at the PD with spectral responsivity $R\left(\lambda \right)$ can be expressed as

(72)$I_{ph}={\int }_{380\mathrm{nm}}^{825\mathrm{nm}}R\left(\lambda \right)\mathcal{A}\left(\lambda \right)\mathsf{\Phi }\left(\lambda \right)d\lambda .$

The DC gain of the proposed channel model for optical inputs and electrical outputs takes the form

(73)$H_{\mathrm{el}}=\frac{I_{ph}}{P_T}=H_{\mathrm{LOS}}^{\mathrm{el}}+H_{\mathrm{NLOS},\left(1\right)}^{\mathrm{el}}.$

Combining Equations (69), (72), and (73), one finds that

(74)$H_{\mathrm{LOS}}^{\mathrm{el}}=\frac{1}{P_T}\int R\left(\lambda \right){\mathcal{A}}_0\left(\lambda \right)\mathsf{\Phi }\left(\lambda \right)d\lambda ,$

(75)$H_{\mathrm{NLOS},\left(1\right)}^{\mathrm{el}}=\frac{1}{P_T}\sum _{w=1}^W\int R\left(\lambda \right){\mathcal{A}}_w\left(\lambda \right)\mathsf{\Phi }\left(\lambda \right)d\lambda .$

2.4.1. Proposed LOS Link

Using the same geometry as the reference channel model and the parameters as in Equation (31), and adding a new spectral transmittance function ${\zeta }_0\left(\lambda \right)$ that accounts for the attenuation caused by scattering and absorption due to dust particles in the LOS link, ${\mathcal{A}}_0\left(\lambda \right)$ can be defined as

(76)${\mathcal{A}}_0\left(\lambda \right)=\mathcal{C}\frac{(m+1)A_R}{2\pi d^2}{\mathsf{\Omega }}_{\mathrm{LOS}}{\mathsf{\Psi }}_{\mathrm{LOS}}\mathcal{G}\left(\lambda \right){\zeta }_0\left(\lambda \right),$

(77)$H_{\mathrm{LOS}}^{\mathrm{opt}}=\mathcal{C}\frac{(m+1)A_R}{2\pi d^2{P}_T}{\mathsf{\Omega }}_{\mathrm{LOS}}{\mathsf{\Psi }}_{\mathrm{LOS}}{\int }_{}\mathcal{G}\left(\lambda \right){\zeta }_0\left(\lambda \right)\mathsf{\Phi }\left(\lambda \right)d\lambda .$

Equivalently, by combining Equation (76) with Equation (74), the proposed DC gain of the electro-optical LOS link can be expressed as

(78)$H_{\mathrm{LOS}}^{\mathrm{el}}=\mathcal{C}\frac{(m+1)A_R}{2\pi d^2{P}_T}{\mathsf{\Omega }}_{\mathrm{LOS}}{\mathsf{\Psi }}_{\mathrm{LOS}}{\int }_{}R\left(\lambda \right)\mathcal{G}\left(\lambda \right){\zeta }_0\left(\lambda \right)\mathsf{\Phi }\left(\lambda \right)d\lambda .$

2.4.2. Proposed NLOS Link

Using the same parameters as Equation (35) and adding a new spectral transmittance function ${\zeta }_w\left(\lambda \right)$ that accounts for the attenuation caused by scattering and absorption due to dust particles in the NLOS link passing through the wth reflector, ${\mathcal{A}}_w\left(\lambda \right)$ can be defined as

(79)${\mathcal{A}}_w\left(\lambda \right)=\frac{(m+1)A_R}{2\pi }{\mathcal{C}}_w\frac{A_{\mathrm{refl},w}}{d_{1,w}^2{d}_{2,w}^2}{\mathsf{\Omega }}_{\mathrm{NLOS}}^{\left(w\right)}{\mathsf{\Psi }}_{\mathrm{NLOS}}^{\left(w\right)}{\rho }_w\left(\lambda \right){\mathcal{G}}_w\left(\lambda \right){\zeta }_w\left(\lambda \right),$

(80)$H_{\mathrm{NLOS},\left(1\right)}^{\mathrm{opt}}=\frac{(m+1)A_R}{2\pi P_T}\sum _{w=1}^W{\mathcal{C}}_w\frac{A_{\mathrm{refl},w}}{d_{1,w}^2{d}_{2,w}^2}{\mathsf{\Omega }}_{\mathrm{NLOS}}^{\left(w\right)}{\mathsf{\Psi }}_{\mathrm{NLOS}}^{\left(w\right)}{\int }_{}{\rho }_w\left(\lambda \right){\mathcal{G}}_w\left(\lambda \right){\zeta }_w\left(\lambda \right)\mathsf{\Phi }\left(\lambda \right)d\lambda .$

Equivalently, combining Equation (79) into Equation (75), the proposed DC gain of the electro-optical single-hop NLOS link can be expressed as

(81)$H_{\mathrm{NLOS},\left(1\right)}^{\mathrm{el}}=\frac{(m+1)A_R}{2\pi P_T}\sum _{w=1}^W{\mathcal{C}}_w\frac{A_{\mathrm{refl},w}}{d_{1,w}^2{d}_{2,w}^2}{\mathsf{\Omega }}_{\mathrm{NLOS}}^{\left(w\right)}{\mathsf{\Psi }}_{\mathrm{NLOS}}^{\left(w\right)}{\int }_{}R\left(\lambda \right){\rho }_w\left(\lambda \right){\mathcal{G}}_w\left(\lambda \right){\zeta }_w\left(\lambda \right)\mathsf{\Phi }\left(\lambda \right)d\lambda .$

2.4.3. Proposed Scattering and Absorption Model

To characterize the effects of dust scattering and absorption in the LOS and NLOS links, transmittance functions ${\zeta }_0\left(\lambda \right)$ and ${\zeta }_w\left(\lambda \right)$ must be defined. Note that in the reference channel, the Rayleigh and Mie scattering regimes contribute exclusively to the scattering-induced NLOS component $H_{\mathrm{scatter}}$, while the absorption effects are not considered in any of the channel components. In contrast, our proposed channel model considers Mie (and not Rayleigh) scattering and absorption effects in both LOS and NLOS links. The exclusion of the Rayleigh regime can be justified by looking at the ratio of the size of the spherical particles to the wavelength, $\alpha =\pi D/\lambda$[30], where D is the diameter of the particle. If $\alpha \ll 1$, then the Rayleigh scattering model is valid. When wavelength and particle size are comparable, Mie scattering theory is more accurate, and when $\alpha \gg 1$, then geometric scattering theory is used [30]. The particle size distribution of airborne particles in underground mines varies depending on the extractive activity, mineral composition, and geology of the mine, but a generalization can be made by looking at several studies conducted in underground coal mines in the United States [31,32], China [30,33], and the former Soviet Union [34] and underground gold mines in Alaska, Nevada, and South Africa [35], all of which show that the particle sizes of coal and silica dust particle sizes are in the order of 1 $\mathsf{\mu }$m to 100 $\mathsf{\mu }$m. Taking into account the wavelengths in the visible spectrum, this range of particle sizes implies that $\alpha$ takes values in the order of 1 to ${10}^3$: that means that Mie theory is the preferred regime for describing the scattering and absorption phenomena in underground mines.

The attenuation of optical channels in non-ideal environments is usually modeled by the Beer–Lambert law, e.g., underwater optical channels [14,36,37], outdoor optical channels degraded by rain and snow [38] and sandstorms [39], and UM-VLC channels attenuated by coal dust [5,30]. The transmittance function $T\left(\lambda \right)$, according to the Beer–Lambert law, is given by [30]:

(82)$T\left(\lambda \right)=exp\left(-{\int }_0^L{B}_{\mathrm{ext}}(\lambda ,\ell )d\ell \right),$

(83)$B_{\mathrm{ext}}(\lambda ,\ell )=\frac{\pi }{4}{N}_p(\ell ){\int }_{x_{p,\min }}^{x_{p,\max }}{x}_p^{2}F(x_p,\ell )Q_{\mathrm{ext}}(x_p,\lambda ,m\left(\lambda \right))d{x}_p,$

(84)$T\left(\lambda \right)=exp\left(-L{B}_{\mathrm{ext}}\left(\lambda \right)\right).$

The Rosin–Rammler (R-R) distribution is widely used in the literature to model the particle size distribution of dust that results from the crushing of solids such as coal, rocks, and other materials and has been empirically validated numerous times [41]. The authors in [30] use the R-R distribution in their calculations of the extinction coefficient of coal dust in underground mines. The authors in [34] also argue that mine dust is best described by the R-R method. Assuming mine dust follows the R-R distribution, then $F\left(x_p\right)$ can be expressed as [30,40]:

(85)$F\left(x_p\right)=1-exp(-{(x_p/{\overline{x}}_p)}^{n_p}),$

The number of coal dust particles $N_p$ can be derived from the mass per unit volume of the mine dust ($\mathrm{mg}/{\mathrm{m}}^3$), $W_p$, which can be found empirically. Given $W_p$, $N_p$ can be expressed as [30]

(86)$N_p=\frac{W_p}{{\rho }_p{C}_v\int x_p^{3}F\left(x_p\right)d{x}_p},$

Considering mine dust consisting of spherical particles and constant particle concentrations and size distributions over the optical link, and combining Equations (83) and (86), the extinction coefficient $B_{\mathrm{ext}}\left(\lambda \right)$ can be expressed as

(87)$B_{\mathrm{ext}}\left(\lambda \right)=\frac{3}{2}\frac{W_p}{{\rho }_p}\frac{\int x_p^{2}F\left(x_p\right)Q_{\mathrm{ext}}(x_p,\lambda ,m\left(\lambda \right))d{x}_p}{\int x_p^{3}F\left(x_p\right)d{x}_p},$

(88)$T\left(\lambda \right)=exp\left(-\frac{3}{2}L\frac{W_p}{{\rho }_p}\frac{\int x_p^{2}F\left(x_p\right)Q_{\mathrm{ext}}(x_p,\lambda ,m\left(\lambda \right))d{x}_p}{\int x_p^{3}F\left(x_p\right)d{x}_p}\right).$

Using Equation (84) and $L=d$ for the LOS component and $L=d_{1,w}+d_{2,w}$ for the wth reflector NLOS component, ${\zeta }_0\left(\lambda \right)$ can be expressed as

(89)${\zeta }_0\left(\lambda \right)=exp\left(-d{B}_{\mathrm{ext}}\left(\lambda \right)\right),$

(90)${\zeta }_w\left(\lambda \right)=exp\left(-(d_{1,w}+d_{2,w})B_{\mathrm{ext}}\left(\lambda \right)\right).$

2.5. Proposed CSK-Based UM-VLC Channel Model

Consider a set of red, green, and blue LEDs with the same characteristics except for different SPDs, given by ${\mathsf{\Phi }}_1\left(\lambda \right)$, ${\mathsf{\Phi }}_2\left(\lambda \right)$, and ${\mathsf{\Phi }}_3\left(\lambda \right)$, respectively, spatially grouped together in such a way that their positions in space can be approximated to be the same from a great enough distance, and three PDs, each with spectral responsivity $R\left(\lambda \right)$ and surface area $A_R$ and filtered by either a red, green, or blue optical filter with spectral gain ${\mathcal{G}}_1\left(\lambda \right)$, ${\mathcal{G}}_2\left(\lambda \right)$, or ${\mathcal{G}}_3\left(\lambda \right)$, respectively, spatially grouped so that their positions in space can be approximated to be the same from a great enough distance. If the distance d between the LEDs and the PDs is large enough, assuming that a unique transmitter position and a unique receiver position is a reasonable approximation, then the electro-optical UM-VLC DC channel gain from the ith LED to the jth PD, with $i,j=1,2,3$, is given by

(91)$H_{\mathrm{el}}[i,j]=H_{\mathrm{LOS}}^{\mathrm{el}}[i,j]+H_{\mathrm{NLOS}}^{\mathrm{el}}[i,j],$

(92)$\begin{array}{c}\hfill \begin{array}{cc}\hfill H_{\mathrm{LOS}}^{\mathrm{el}}[i,j]& =\frac{1}{P_{T,i}}{\int }_{}R\left(\lambda \right){\mathcal{A}}_{0,j}\left(\lambda \right){\mathsf{\Phi }}_i\left(\lambda \right)d\lambda ,\hfill \\ \hfill & =\mathcal{C}\frac{(m+1)A_R}{2\pi d^2{P}_{T,i}}{\mathsf{\Omega }}_{\mathrm{LOS}}{\mathsf{\Psi }}_{\mathrm{LOS}}{\int }_{}R\left(\lambda \right){\mathcal{G}}_j\left(\lambda \right){\zeta }_0\left(\lambda \right){\mathsf{\Phi }}_i\left(\lambda \right)d\lambda ,\hfill \end{array}\end{array}$

(93)$\begin{array}{c}\hfill \begin{array}{cc}\hfill H_{\mathrm{NLOS}}^{\mathrm{el}}[i,j]& =\sum _{w=1}^W{H}_{\mathrm{NLOS},w}^{\mathrm{el}}[i,j],\hfill \\ \hfill & =\frac{1}{P_{T,i}}\sum _{w=1}^W{\int }_{}R\left(\lambda \right){\mathcal{A}}_{w,j}\left(\lambda \right){\mathsf{\Phi }}_i\left(\lambda \right)d\lambda ,\hfill \\ \hfill & =\frac{(m+1)A_R}{2\pi P_{T,i}}\hfill \\ \hfill & \times \sum _{w=1}^W{\mathcal{C}}_w\frac{A_{\mathrm{refl},w}}{d_{1,w}^2{d}_{2,w}^2}{\mathsf{\Omega }}_{\mathrm{NLOS},i}^{\left(w\right)}{\mathsf{\Psi }}_{\mathrm{NLOS}}^{\left(w\right)}{\int }_{}R\left(\lambda \right){\rho }_w\left(\lambda \right){\mathcal{G}}_{w,j}\left(\lambda \right){\zeta }_w\left(\lambda \right){\mathsf{\Phi }}_i\left(\lambda \right)d\lambda .\hfill \end{array}\end{array}$

Note that if we consider that optical filters do not depend on incident angle ${\theta }_w$, then we can relax the definition to ${\mathcal{G}}_{w,j}\left(\lambda \right)\equiv {\mathcal{G}}_j\left(\lambda \right)$. Furthermore, ${\mathsf{\Omega }}_{\mathrm{NLOS},i}^{\left(w\right)}$ depends on the ith LED, since we consider that the light that bounces off the wth reflector will have different angles of irradiance depending on the LED from which the light comes. This is to account for the irregularity of the underground tunnel walls, where a slight displacement of the light source can have great effects on the angle of reflection off the wall. Since the LEDs are slightly displaced from each other, it is safe to assume that light from different LEDs will bounce off the walls independently. In practice, we model the wth reflector differently for each LED, such that it has a rotation angle ${\alpha }_{1,w}$ and a tilt angle ${\beta }_{1,w}$ for light coming from the red LED; a rotation angle ${\alpha }_{2,w}$ and a tilt angle ${\beta }_{2,w}$ for light coming from the green LED; and a rotation angle ${\alpha }_{3,w}$ and a tilt angle ${\beta }_{3,w}$ for light coming from the blue LED. For each wth reflector, these six angles are modeled as uniform random variables, drawn independently. We have for the tilt angles ${\beta }_{1,w},{\beta }_{2,w}$, ${\beta }_{3,w}$ that

(94)${\beta }_{1,w},{\beta }_{2,w},{\beta }_{3,w}\sim \mathcal{U}[0,\pi ],\forall w=1,\cdots ,W,$

(95)${\alpha }_{1,w},{\alpha }_{2,w},{\alpha }_{3,w}\sim \mathcal{U}[0,\pi ],\forall w\in \{w\mid y_w=0\},$

(96)${\alpha }_{1,w},{\alpha }_{2,w},{\alpha }_{3,w}\sim \mathcal{U}[\pi ,2\pi ],\forall w\in \{w\mid y_w=L_y\}.$

Figure 3 illustrates the channel components of the proposed CSK-based UM-VLC channel. Finally, the channel impulse response for the UM-VLC channel between the ith LED and the jth PD is given by [25]

(97)$h[i,j]\left(t\right)=H_{\mathrm{LOS}}^{\mathrm{el}}[i,j]·\delta \left(t-\frac{d}{c}\right)+\sum _{w=1}^W{H}_{\mathrm{NLOS},w}^{\mathrm{el}}[i,j]·\delta \left(t-\frac{d_{1,w}+d_{2,w}}{c}\right).$

3. Results and Discussion

3.1. Simulation Parameters

For the simulation scenario, we consider a mining roadway with a single CSK transmitter at a fixed position and a single CSK receiver in a miner’s helmet (hence, we position the height of RX at 1.8 m), free to move anywhere in the x–y plane of the tunnel. The spatial dimensions of the scenario and the channel parameters used in this work are defined in Table 2. All the spectral parameters used in the simulation are presented in Figure 4.

The SPDs for each LED, ${\mathsf{\Phi }}_1\left(\lambda \right),{\mathsf{\Phi }}_2\left(\lambda \right),{\mathsf{\Phi }}_3\left(\lambda \right)$, are collected from [42] and were selected because they have already been used in an experimental CSK setup in [10,24]. Their dominant wavelengths are in the ranges ${\lambda }_R\in [620,645]$ (nm), ${\lambda }_G\in [520,540]$ (nm), and ${\lambda }_B\in [460,485]$ (nm) for the red, green, and blue LEDs, respectively.

UM-VLC system parameters.