SCATTERING OF ELECTROMAGNETIC WAVE BY OFFSET

SPHERICAL PARTICLES

Felix O. Ngobigha and David H. O. Bebbington

School of Computer Science and Electronic Engineering, University of Essex,

Wivenhoe Park, Colchester CO4 3SQ, United Kingdom

{ fngobi, david } @essex.ac.uk

Keywords: Offset spherical particle, T-matrix method, electromagnetic waves scattering.

Abstract: The Lorentz–Mie theory is applicable to calculating scattering characteristics of spherical shaped particles.

It is often applied to slightly non-spherical particles where its range of validity is uncertain. This paper

defines the range of validity of the T-matrix technique of Barber and Hill as applied to homogeneous

spherical and non-spherical particles. Scattering calculations are made for a set of non-absorbing

homogeneous spherical particles with the origin of the particle offset over a certain range. The numerical

results show that even for small offset value with the same input parameters, the phase function, extinction

and scattering cross sections differ quite significantly compared to the generalized Lorentz–Mie technique

known to give accurate scattering characteristics for spherical particle.

1 INTRODUCTION

The scattering of electromagnetic waves by

spherical object is a problem that has received

increased attention in past and recent years.

Knowledge of the scattered field is required in many

areas of science and engineering applications. The

idea was first developed by Gustav Mie in 1908 in

order to understand the colours that resulted from

light scattering of gold particles suspended in water.

Applications of Mie solution has been extended

from one end of the electromagnetic spectrum to the

other, from Ultraviolent solar radiation

backscattered by stratospheric aerosols to satellites,

through visible and Infrared radiation scattered by

clouds and aerosols, to microwaves and radar

scattered from large hydrometeors. An excellent

introduction to the theory is reported in (Kerker

1969; van de Hulst 1981; Mishchenko, Travis et al.

2002; Bohren and Huffman 2008). Although, the

Mie-theory it is exact, but with the emergence of

computing it has become practical to calculate

various scattering characteristics (Wiscombe 1980).

The Mie-theory has limitation of being restricted to

spherical particles. However, it has served as a

reference for validation of other techniques for

evaluating scattering properties from scatterers, and

implementation of this theory with slightly non-

spherical particles has yielded similar results.

This paper deals with the range of validity of T-

matrix method reported in (Barber and Hill 1990) as

applied to a lossless dielectric spherical particle with

the origin moved of centre over a certain range. Our

aim is show the uncertainty with reference to

particle shape when calculating scattering cross

sections in which the origin is displaced from the

centre of the spherical object as previously reported

(Waterman 1965; Barber and Yeh 1975; Barber and

Hill 1990) by adopting and implementing the code

in (Barber and Hill 1990) and not the theoretical

analysis as numerous papers have already addressed

this aspect. Nevertheless, the results in the cited

references differ with ours. Clearly, the final results

given in this paper are not new. Rather, our

contribution is based on offset range validity at

various frequency bands with the goal of providing a

consistent result regardless of the mathematics that

led to their derivation.

135

O. Ngobigha F. and H. O. Bebbington D.

SCATTERING OF ELECTROMAGNETIC WAVE BY OFFSET SPHERICAL PARTICLES.

DOI: 10.5220/0004786301350139

In Proceedings of the Second International Conference on Telecommunications and Remote Sensing (ICTRS 2013), pages 135-139

ISBN: 978-989-8565-57-0

2 RELATED WORK

The approach adopted in this paper was originally

introduced by P C Waterman (Waterman 1965) as a

technique for computing electromagnetic scattering

by a smooth, perfectly conducting, homogeneous,

arbitrarily shaped particle illuminated by an incident

plane electromagnetic wave. This technique is also

known as null field method (Zheng 1988) or

extended boundary condition method (EBCM)

(Barber and Wang 1978), and is developed further

by (Barber and Yeh 1975), (Mishchenko and Travis

1994; Mishchenko, Travis et al. 1996; Mishchenko

and Travis 1998; Mishchenko, Hovenier et al. 1999).

The technique has also gained wide acceptance in

the field of electromagnetic waves scattering due to

its capability to calculate the scattering properties of

arbitrarily shaped scatterers. The approach of the T-

matrix formulation utilizes vector spherical

harmonic function expansions of the incident and

scattered fields in conjunction with boundary

conditions at the surface of the scattering particles to

obtain a system of linear equations relating the

unknown expansion coefficients of the scattered

field to the known coefficients of the incident field.

The most attractive feature of T-matrix technique

starts as Lorenz-Mie theory when the scattering

particle is homogeneous or layered sphere composed

of isotropic materials.

Given a specific scattering object, first step is to

select an internal origin on the scattering particle and

surround the object with imaginary sphere of radius

large enough to circumscribe the scatterer

(Barber and Hill 1990; Mishchenko, Travis et al.

2002), and numerically perform the surface

integrations over the scatterer which are required to

fill the coefficient matrix. The next step is to carry

out matrix operation to obtain the scattered field

coefficients

and . The final step then is to

substitute the scattered field coefficients into (1) to

yeild the scttered field and other desire

characteristics.

()

() ()

Ekr

E D f M kr g N kr

λλ

ννν νν

∞

⎡⎤

×+

⎣⎦

∑

(1)

where M and N are the vector spherical harmonic

functions and the superscript 3 on

and

indicates that these functions are of the type suitable

for radiation or outgoing fields (Hankel function),

represents the spherical harmonic triple index

(even or odd), m, n. The argument of the vector

spherical wave functions

, where

denotes wave number in the surrounding medium,

is the incident wavelength, and is the position

vector which defines a point in three-dimensional

space. The

is the amplitude of the incident

electric field, and

denotes normalization

constant.

The important formulas for Mie scattering are

well defined (Kerker 1969). The quantities required

at this level are summarized. The amplitude matrix

for spherical object is a diagonal matrix; due to

symmetry it takes the form:

ikr

⊥⊥

⎛⎞ ⎛⎞

⎛⎞

⎜⎟ ⎜⎟

⎜⎟

⎜⎟ ⎜⎟

⎝⎠

⎝⎠ ⎝⎠

(2)

where

(

)

()

() ()

cos cos

nn nn

θτ θ

∞

Θ=

⎡

⎤

⎣

⎦

∑

(3)

(

)

()

() ()

cos cos

nn nn

θτ θ

∞

Θ=

⎡

⎤

⎣

⎦

∑

(4)

which are respectively, scattered electric field and

complex scattering amplitude for the two orthogonal

directions of incident polarization.

and

are the scattered intensities, and are

the angular function,

and are Mie expansion

coefficients in terms of the vector spherical

harmonic, depend on the size parameter and on the

complex refractive index. They are also expressed in

terms of spherical Bessel functions.

3 SIMULATION RESULTS

An incident plane polarized wave propagating in the

direction is assumed, with the origin of the

scatterer coincides with the spherical coordinate

system for the calculation of differential scattering

Second International Conference on Telecommunications and Remote Sensing

136

cross section of spherical, and slightly non-spherical

particles. Some of the input parameters such as size

parameter

and refractive index

(

)

are chosen to compare results (van de Hulst 1981).

For a sphere,

is the radius of the scattering object

but for non-spherical particles (oblate or prolate

spheroid), the choice of

gives users the option of

defining

as the radius of a sphere of either equal

volume, or equal surface area to that of the

scattering object while for offset spherical particle, it

is the distance from the origin of the spherical

coordinate system to the surface of offset spherical

scatterer calculated by applying Pythagoras or

Cosine rule.

Numerical illustrations confirm that the results

for spherical bodies are identical at different

frequencies compared to those obtained by the Mie

theory. The check was extended to slightly non-

spherical particles (oblate and prolate spheroids); a

similar agreement is generally observed for both

particles. The vertical and horizontal polarizations

are denoted

and respectively.

0 20 40 60 80 100 120 140 160 180

-4

-3

-2

-1

scatterin

le, de

rees

Differential Scattering cross section

VV(Mie)

HH(Mie)

VV(T-matrix)

HH(T-matrix)

Figure 1: Comparison of Mie-theory and T-Matrix method

for differential scattering cross sections of non-absorbing

spherical and offset spherical particles at 220 GHz.

0 20 40 60 80 100 120 140 160 180

-3

-2

-1

scatterin

rees

Differential Scattering cross section

VV(Mie)

HH(Mie)

VV(T-matrix)

HH(T-matrix)

Figure 2: Comparison of Mie-theory and T-Matrix method

for differential scattering cross sections of non-absorbing

oblate spheroid at 94 GHz.

0 20 40 60 80 100 120 140 160 180

-3

-2

-1

scatterin

le, de

rees

Differential Scattering cross section

VV(Mie)

HH(Mie)

VV(T-matrix)

HH(T-matrix)

Figure 3: Comparison of Mie-theory and T-Matrix method

for differential scattering cross sections of non-absorbing

prolate spheroid at 94 GHz.

0 20 40 60 80 100 120 140 160 180

-3

-2

-1

scattering Angle, degrees

Differential Scattering cross section

offset VV=0.0

offset VV=0.006

offset VV=0.013

offset VV=0.025

offset VV=0.051

Figure 4: Comparison of Mie-theory and T-Matrix method

for non-absorbing spherical and offset spherical particles

at 94 GHz.

Scattering of Electromagnetic Wave by Offset Spherical Particles

137

0 20 40 60 80 100 120 140 160 180

-1.7

-1.6

-1.5

scattering Angle, degrees

Differential Scattering cross section

offset HH=0.0

offset HH=0.006

offset HH=0.013

offset HH=0.025

offset HH=0.051

Figure 5: Comparison of Mie-theory and T-Matrix method

non-absorbing spherical and offset spherical particles at 94

GHz.

0 20 40 60 80 100 120 140 160 180

-2

-1

scattering Angle, degrees

Differential Scattering cross section

offset VV=0.0

offset VV=0.102

offset VV=0.204

offset VV=0.408

offset VV=0.816

Figure 6: Comparison of Mie-theory and T-Matrix method

for non-absorbing spherical and offset spherical particles

at 5.8 GHz.

0 20 40 60 80 100 120 140 160 180

scattering Angle, degrees

Differential Scattering cross section

offset HH=0.0

offset HH=0.102

offset HH=0.204

offset HH=0.408

offset HH=0.816

Figure 6: Comparison of Mie-theory and T-Matrix method

for non-absorbing spherical and offset spherical particles

at 5.8 GHz.

It is evident from Figure 1 that our results for

both approach show good agreement with (Barber

and Yeh 1975; Barber and Hill 1990) and

(Waterman 1965) regardsless of the scatterer (i.e.

spherical or offset spherical particles) at 220 GHz.

This is also observed in Figure 2 and 3 comparing

Mie-theory and T-Matrix method for differential

scattering cross sections of non-absorbing spheroid

at 94 GHz.

Evaluation of results from Mie-theory and T-

Matrix method for non-absorbing spherical and with

the spherical particle origin moved over a range at

94 GHz for vertical polarization still show

reasonable agreement, but with horizontal

polarization in Figure 5, it is obvious that the

differential scattering cross-sections increases as the

offset range increases, this effect is least noticed

with increase in scattering angle. This shows that at

higher operating frequencies the effect is

insignificant; however, Figure 6 and 7 results show

that even for small offset value with the same input

parameters, the phase function, extinction and

scattering cross sections differ quite significantly at

5.8 GHz compared to the generalized Lorentz–Mie

technique.

4 CONCLUSIONS

We have demonstrated in our results that the effect

of offset values relative to the frequency bands and

how the scattering calculation in terms of geometric

properties of the particles; (shapes and size

parameter) for spherical and slightly non-spherical

particles adopting Mie theory and T-matrix

techniques are similar with previous works at higher

frequency bands. Furthermore, the same trends of

results are observed in terms of vertical polarization

for non-absorbing offset spherical scatterer at 94

GHz. On the other hand, scattering characteristics

for horizontal polarization at 94 GHz, and at lower

frequency bands (i.e. 5.8 GHz) differs quite

significantly with the same input parameters. Hence,

scattering calculation from non-absorbing

homogeneous spherical particles with the origin of

the particle moved over a certain range should be

used with caution depending on the wave frequency.

This is particularly important due to previous

concept that the same scattered cross section is

obtained with the origin of the spherical scatterer at

the centre. Obviously, the difference in our results

with the former at lower frequency (i.e. 5.8 GHz)

would lead to erroneous values being generated as

the offset value increases and tends toward the

Second International Conference on Telecommunications and Remote Sensing

138

radius of scattering object, and inaccurate prediction

of hydrometeor shapes are likely if the previous

concept is applied in radar and remote sensing

applications.

ACKNOWLEDGEMENT

This work was supported by Petroleum Technology

Development Fund (PTDF) under scholarship

number PTDF/E/OSS/PHD/NF/355/11.

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Scattering of Electromagnetic Wave by Offset Spherical Particles

139