The Impact of Information Geometry on the Analysis of the Stable

M/G/1 Queue Manifold

Ismail A. Mageed and Demetres D. Kouvatsos

Department of Computer Science, Faculty of Engineering and Informatics,

University of Bradford, Bradford, BD7 1DP, U.K.

Keywords: Stable M/G/1 Queue, Maximum Entropy (ME), Information Geometry (IG), Statistical Manifold (SM), Queue

Manifold (QM), Ricci Curvature (RC), Riemannian Metric (RM), Fisher Information Matrix (FIM),

Kullback’s Divergence (KD), J-divergence (JD), Information Matrix Exponential (IME).

Abstract: Information geometry (IG) provides the characterization of the structure of statistical models from a

differential geometric point of view. By considering families of probability distributions as manifolds with

coordinate charts determined by the parameters of each individual model, the tools of differential geometry,

such as divergences and metric tensors, provide effective means of studying their characteristics. The research

undertaken in this paper presents a novel approach to the modelling study of information geometrics of a

queueing system. In this context, the manifold of stable M/G/1queue is characterised from the viewpoint of

IG, the Kullback’s divergence (KD) and J-divergence (JD) are determined. Also, it is revealed that the stable

M/G/1 queue manifold has a zero 0 -Gaussian curvature a non-zero Ricci Curvature Tensor (RCT). Unifying

IG with Queueing Theory enables the study of dynamics of queueing system from a novel Riemannian

Geometry (RG) point of view, leading to the analysis of the stable M/G/1 queue, based on Theory of Relativity

(TR).

1 INTRODUCTION

Information geometry (IG) has been widely applied

in many research fields such as statistical inference,

stochastic control and neural networks (c.f., Amari,

1985) In other words, IG aims to apply the techniques

of differential geometry (DG) to statistics. This

means that IG’s main idea is to apply methods and

techniques of non-Euclidean geometry to stochastic

processes and probability theories. IG indicates that

the use of an Euclidian geometry technique is useful

to think of a family of probability distributions as a

statistical manifold (SM). Moreover, IG has been

adopted for the study of statistical manifolds (SMs),

where the geometric metrics gave a new description

of the probability density function which plays an

important role in SM and can be regarded as the

coordinate system.

A manifold (c.f., Škoda, 2019) is a topological

finite dimensional Cartesian space, ℝ



, where one

has an infinite-dimensional manifold. ℝ



could be

described merely as topological space (may be

defined as a set of points, along with a set of

neighbourhoods for each point, satisfying a set of

axioms relating points and neighbourhoods). In

addition, IG supports reasoning intuitively the

description of SMs. Note that although figures can be

visualised (i.e., plotted in coordinate charts), they

should be thought of as purely abstract figures,

namely, geometric figures. One may have a higher

level of appreciation of the significant importance of

IG (c.f., Nielsen, 2018). In Figure 1, the parameter

inference 𝜃

∧

of a model from data can be interpreted

as a decision-making problem: One has to decide

which parameter of a family of models 𝑀={𝑚



}



suits “best’’ the data, where Θ is the set of parameters

{𝜃



,𝜃



,..,𝜃



} of the probability density function of

the distribution of the geometric manifold. IG

provides a differential-geometric manifold

structure 𝑀 that is useful for developing decision

rules. In (Amari, 1985), the exponential distribution

families were investigated whilst (Dodson, 1999)

studied some special exponential distributions such as

the bivariate normal distribution, the Gamma

distribution, the McKay distribution and the Frund

distribution and revealed their geometric structures.

In this paper, a study is undertaken of the

geometric structure of the stable M/G/1 queue

A. Mageed, I. and Kouvatsos, D.

The Impact of Information Geometry on the Analysis of the Stable M/G/1 Queue Manifold.

DOI: 10.5220/0010206801530160

In Proceedings of the 10th International Conference on Operations Research and Enterprise Systems (ICORES 2021), pages 153-160

ISBN: 978-989-758-485-5

153

manifold (QM) as well as finding its information

matrix exponential (IME). The (IME) is a matrix on

square matrices analogous to the ordinary exponential

function.

Figure1: Parametrization of a SM (c.f., Nielsen, 2018).

It is used to solve systems of linear differential

equations. In addition to that, the matrix exponential

plays a crucial role in the theory of Lie groups (c.f.,

Hall, 2015). To our knowledge, there is only one

research paper (c.f., Nakagawa, 2002), which studied

the IG of a stable M/D/1 queues, where a geometric

structure was introduced on the set of M/D/1 queues

by employing the properties of queue length paths.

This point of view motivated the novel track of the

research of this paper linking IG with information

matrix theories towards a new re-interpretation of the

stable M/G/1 queue. In this context, by analogy to

information theory (IT), the geometric approach

adopted in this paper enables the study of invariance

and equivariance of figures in a coordinate-free

approach (n.b., by equivariance as a concept, it is

meant when there is a group acting on a pair of spaces

and there is a map from functions on one to the

functions on the other (c.f., Kondor and Trivedi,

2018). In the context of this paper, Ricci curvature

(c.f., Nielsen, 2020) measures the deviation of the

Riemannian metric (RM) from the standard

Euclidean metric (EM) and how scalar curvature

measures the deviation in the volume of a geodesic

ball from the volume of an Euclidean ball of the same

radius (c.f., Figure 2).

Figure 2: Geometric representation of geodesics on curved

surfaces (c.f., Norton, 2020).

In IG, the Fisher information metric (FIM) is a

particular Riemannian metric (RM), which can be

defined on a smooth statistical manifold (i.e., a

smooth manifold whose points are probability

measures defined on a common probability space). It

can be used to calculate the informational difference

between measurements. The FIM measures closeness

of the shape between two distribution functions, it is

also proportional to the amount of information that

the distribution function contains about the parameter

of the probability density function of the SM. The

focus of this work is foundational with the following

list of its contributions:

i) The FIM and its inverse as well as the FIM for the

stable M/G/1 QM are introduced.

ii) A novel 𝛼 (or ∇

(



)

)-connection (the 𝛼−

connection

(

c.f.,Dodson,2005

)

,maps each co

ordinate 𝜃



𝑜f 𝜃,𝑖=1,2,3,…,𝑛 to a value. In

particular, the 1-connection (or, ‘exponential

connection’) and the (-1) – connection (or,

‘mixture connection’) of a stable M/G/1 queue

manifold are devised. iii) The KD and the JD of a

stable M/G/1 queue are determined. iv)The stable

M/G/1 queue’s manifold could be considered to

be incompressible or solenoidal, in which case

any closed surface has no net flux across it (n.b.,

A flux is a vector quantity, describing the

magnitude and direction of the flow of a substance

or property c.f., Divergence Theorem by (c.f.,MIT

Open Course Ware, 2010), which is the second 3-

dimensional analogue of Green’s Theorem stating

that ‘If F is a vector ﬁeld with continuous

derivatives deﬁned on a region D ⊆ 𝑅



with

boundary curve C, then, the ﬂux of F across C is

equal to the integral of the divergence over its

interior’). v) The exponential of the FIM for the

stable M/G/1 queue is shown to be a solution of a

differential equation of the form





= Ax, where x

is an n-dimensional vector and A is an nxn matrix.

This paper is a major extension of a short paper by

(Mageed and Kouvatsos, 2019) with the following

contributions:

• The determination of the Kullback Divergence

and the J-divergence of the stable M/G/1 QM.

• The proof that the exponential of the Fisher

information matrix of the stable M/G/1 QM is a

solution of a differential equation of the form





Ax.

The main original contributions of this paper are

described below.

• The inclusion of the definitions of Gaussian and

Ricci curvatures and their physical

interpretations;

• The proposed novel approach for the pioneer

visualization of queueing systems via

computational information geometry;

• The development of a new quantitative approach

(which hadn’t been discovered at the time we

presented our UKPEW 2019;

• The determination of new important links

between classical queueing theory and other

mathematical disciplines, such as IG, matrix

theory Riemannian geometry and the Theory of

ICORES 2021 - 10th International Conference on Operations Research and Enterprise Systems

154

Relativity by providing for first time i) The full

detailed derivations of the Gaussian curvature ii)

The Ricci curvature tensor and iii) The full

physical as well as the geometric interpretation of

these new results;

• The provision of a novel link between Ricci

Curvature (RCT) and the stability analysis of the

stable M/G/1 QM.

The rest of this paper is organised as follows:

Section 2 presents preliminary definitions associated

with (IG). The FIM and its inverse as well as the

Fisher information metric for a stable M/G/1 queue

manifold are introduced in Section 3. The 𝛼(or ∇

()

connection of a stable M/G/1 queue manifold is

obtained in Section 4. The KD and JD (c.f., Peng, Sun

and Jiu, 2007) of a stable M/G/1 QM are obtained in

Section 5. The structured proofs that the stable M/G/1

queue manifold has a non-zero Ricci Curvature

Tensor (RCT) is devised in Section 6. The

exponential matrix analysis of a stable M/G/1 queue

is obtained in Section 7. Conclusions and future

research directions are included in Section 8.

2 MAIN DEFINITIONS IN IG

Definition 2.1: Statistical Manifold (SM).

𝑀={𝑝(𝑥,𝜃)|𝜃ϵΘ} is called an SM (c.f., Li, Sun, Tao

and Jiu, 2007) if x is a random variable in sample

space 𝑋 and 𝑝(𝑥,𝜃) is the probability density

function, which satisfies certain regular conditions.

Here, 𝜃=(𝜃



,𝜃



,..,𝜃



)ϵΘ is an n-dimensional

vector in some open subset Θ⊂ℝ



, and 𝜃 can be

viewed as the coordinates on manifold M.

Definition 2.2: Potential Function. The potential

function Ψ

(

𝜃

)

(c.f., (2.1)) (c.f., Li, Sun, Tao and Jiu,

2007) is the distinguished negative function of the

coordinates alone of (ℒ

(

𝑥;𝜃

)

=𝑙𝑛𝑝

(

𝑥;𝜃

)

) and in

a sequel, it will appear in the information geometric

analysis of the M/G/1 queue manifold.

Definition 2.3: Fisher’s Information Matrix

(FIM). The FIM (or, Fisher’s metric) [ 𝑔



] (c.f.,

Dodson, 2005) is given by the Hessian (the nxn

matrix of the partial derivatives of the potential

function Ψ(𝜃) with respect to the coordinates) i.e.,

𝑔



=

∂



∂𝜃



∂𝜃



Ψ

(

𝜃

)

,𝑖,

𝑗

=1,2,..,𝑛 (2.1)

with respect to natural coordinates.

Definition 2.4: Inverse Matrix of Fisher’s

Information Matrix (FIM). Given the FIM, the

inverse matrix of [𝑔



] is defined by (c.f., Dodson,

2005).

[𝑔



]= ([𝑔



]) )













∆

, ∆= det𝑔





(2.2)

The FIM for the manifold M is given

in 𝜃 coordinates by the arc length function.

(𝑑𝑠)



= 𝑔





,

(𝑑𝜃



)(𝑑𝜃



)

(2.3)

Definition 2.5: 𝜶-Connection. For each 𝛼𝜖ℝ, the

𝛼(or ∇

()

)-connection (c.f., Dodson, 2005) is the

torsion-free affine connection with components:

,

()

= (





)(𝜕



𝜕



𝜕



(Ψ

(

𝜃

)

))

(2.4)

where 𝛹(𝜃) is the potential function and 𝜕









Definition 2.6: Kullback’s Divergence (KD),

𝑲

(

𝒑,𝒒

)

. Assume 𝑝𝑥;𝜃



 and 𝑞𝑥;𝜃



 are two

points on the manifold M, the Kullback’s divergence

𝐾

(

𝑝,𝑞

)

(c.f., Li, Sun, Tao and Jiu, 2007) is defined

𝐾

(

𝑝,𝑞

)

=𝐸





𝑙𝑛 

;





;





=∫𝑝



𝑥;𝜃





𝑙𝑛

;





;





𝑑𝑥

(2.5)

where 𝐸





stands for the expected value and the J-

divergence is defined by

𝐽

(

𝑝,𝑞

)

=∫𝑙𝑛



𝑝𝑥;𝜃





𝑞𝑥;𝜃











;









;







𝑑𝑥

(2.6)

When the two 𝑝(𝑥;𝜃



) and 𝑞(𝑥;𝜃



) are close

enough and by using Taylor’s formula, the following

analytic (c.f., Li, Sun, Tao and Jiu, 2007) result holds:

𝐾

(

𝜃,𝜃+𝑑𝜃

)

𝐽

(

𝜃,𝜃+𝑑𝜃

)

(𝑑𝑠)



where (𝑑𝑠)



stands for the square of the arc length of

the manifold.

Definition 2.8:

1. Under the 𝜃 coordinate system, the 𝛼−

curvature Riemannian Tensors, 𝑅



()

(c.f., Li,

Sun, Tao and Jiu, 2007) are defined by

𝑅



()

=𝜕



𝛤





(



)

−𝜕



𝛤





(



)

𝑔



+𝛤

,

(



)

𝛤





(



)

−𝛤

,

(



)

𝛤





(



)

,𝑖,

𝑗

,𝑘,𝑙,𝑠,𝑡

=1,2,3,….,𝑛

(2.7)

where 𝛤





(



)

= 𝛤

,

(



)

𝑔



, i,j,k,s = 1,2,...,n

2. The 𝛼− Ricci curvatures (Ricci Tensors) 𝑅



()

are determined by (c.f., Li, Sun, Tao and Jiu,

2007).

𝑅



()

=𝑅



()

𝑔



,𝑖,

𝑗

,𝑘,𝑙=1,2,3,….,𝑛

(2.8)

3. The 𝛼−sectional curvatures 𝐾



()

are defined

by (c.f., Li, Sun, Tao and Jiu, 2007).

The Impact of Information Geometry on the Analysis of the Stable M/G/1 Queue Manifold

155

𝐾



()





()

(





)









(



)



,𝑖,

𝑗

=1,2,…,𝑛

(2.9)

Specifically, if 𝑛=2, the 𝛼−

sectional curvature 𝐾



(



)

= 𝐾

(



)

is called 𝛼−

Gaussian curvature and is given by (c.f., Li, Sun,

Tao and Jiu, 2007).

𝐾

(



)





()











(2.10)

4. The Ricci Tensor (c.f., Loveridge, 2016) is simply

a contraction of the Riemannian Tensor (c.f., Li,

Sun, Tao and Jiu, 2007).

5. The Ricci curvature Tensor (RCT) (c.f., Rudelius,

2012) of an oriented Riemannian Manifold M

means the extent to which the volume of a

geodesic ball on the surface differs from the

volume of a geodesic ball in Euclidean space.

6. The Ricci curvature (RCT) (c.f., Ollivier, 2010)

contracts the evolution of volumes under the

geodesic flow. When Ricci curvature is positive,

then according to the Bonnet Myers theorem (c.f.,

Ollivier, 2010) the Riemannian manifold is more

positively curved than a sphere and the diameter

of the manifold is smaller.

Figure 3: (RCT) describes how conical regions in the

manifold differ in volume from the equivalent conical

regions in Euclidean space (c.f., Thomas, 2015).

Definition 2.9:

1. Considering the linear system of differential

equations





𝐴

𝑥

(2.11)

with x is an n-dimensional vector and A is an nxn

matrix. It can be shown that (Gunawardena, 2006) the

matrix exponential

𝑒



∑





!





= 𝐼+

𝐴





!

+⋯+





!

+....

(2.12)

is the solution of (2.11).

2. If the characteristic polynomial of A is defined by

(

𝛿

)

=det

(

A−δI

)

(2.13)

then, the set of eigen values of A will is defined to be

(c.f., Gunawardena, 2006) the set of all the roots of

the equation

(

𝛿

)

(

𝛿

)

=det

(

A−δI

)

= 0

(2.14)

and corresponding eigen vectors x assigned to each

eigen value 𝛿 are defined to satisfy the equation:

𝐴

𝑥= 𝛿𝑥

(2.15)

Another way to represent 𝑒



will be

𝑒



=𝑇𝑒



𝑇



(2.16)

where D is the diagonal matrix of eigen values of A,

and T is matrix having of the corresponding eigen

vectors of A as its columns (c.f., Gunawardena, 2006).

3 THE FIM AND ITS INVERSE

FOR THE STABLE M/G/1 QM

According to (El-Affendi and Kouvatsos, 1983), the

maximum entropy (ME) state probability of the

generalized geometric solution of a stable M/G/1

queue (c.f., Figure. 4), subject to normalisation, mean

queue length (MQL), L and server utilisation, 𝜌(<1)

is given by

Figure 4: A Stable M/G/1 queue.

𝑝

(

𝑛

)

=

1−𝜌, 𝑛=0

(

1−𝜌

)

𝑔𝑥



,𝑛≥1

(3.1)

where 𝑔=





(



)(



)

,𝑥=





and 𝐿=

















(MQL of Pollaczeck-Khinchin Formula of a

stable M/G/1 queue), 𝜌 = 1 – 𝑝

(

)

(server utilisation)

and 𝐶





(SCV of the service times).

It clearly follows that 𝑝

(

𝑛

)

of (3.1) can be

rewritten as

𝑝

(

𝑛

)

⎩

⎪

⎨

⎪

⎧

1−𝜌, 𝑛=0

2𝜌(

1+𝜌𝛽

1−𝜌

−1)



(

1+𝜌𝛽

1−

𝜌

+1)



, 𝑛≥ 0 , with 𝛽= 𝐶





(3.2)

Theorem 3.1. For the stable M/G/1 queue manifold,

it holds that

(i) The FIM is given by

[𝑔



] = 



()





(



)





(3.3)

(ii) The square of the arc length (i.e., Fisher

Information Metric) is determined by

(𝑑𝑠)



= (



()



)(𝑑𝜌)





(



)



(𝑑𝛽)



(3.4)

(iii) The inverse of Fisher Information Matrix is

given by

[𝑔



] =











∆

= 

(1 − 𝜌)



0−(𝛽+1)





(3.5)

Proof. Following (3.2), two cases would arise.

Case I: For 𝑛=0, 𝑝

(

𝑛

)

=1−𝜌. Hence, the

coordinate system is one dimensional satisfying

ICORES 2021 - 10th International Conference on Operations Research and Enterprise Systems

156

ℒ

(

𝑥;𝜃

)

=𝑙𝑛𝑝

(

𝑥;𝜃

)

= 𝑙𝑛

(

1−𝜌

)

𝜃= 𝜃



= 𝜌

(3.6)

The potential function Ψ

(

𝜃

)

will be the standalone

part of (- ℒ

(

𝑥;𝜃

)

)involving the coordinates, i.e.,

(

𝜃

)

=−𝑙𝑛

(

1−𝜌

)

(3.7)

Thus,

𝜕



𝜕Ψ

𝜕𝜌

1−𝜌

(3.8)

𝜕



𝜕



𝜕



𝜕𝜌



(1−𝜌)



(3.9)

FIM is given by

[𝑔



] = 











= 



()





(3.10)

The inverse of the FIM is determined by

[

𝑔



]

=[𝑔



]



[

(1 − 𝜌)



]

(3.11)

Moreover,

,

()

= (



()



) , Γ



()



()

, Γ



()



()

(3.12)

Following the same argument, the proofs of (ii)

and (iii) follow.

4 𝐓𝐡𝐞 𝜶(OR 𝛁

(𝛂)

)-CONNECTION

OF THE M/G/1 QM

By definition (2.8), we have

,

()

()

()



(4.1)

Similarly, the remaining components are devised.

Furthermore, after some lengthy calculations

𝛤

(

𝛼

)

1−𝛼

(1−𝜌)

,𝛤

(

)

(1−𝜌)

(4.2)

𝛤





(



)

= −

1−𝛼

(

1+𝛽

)

,𝛤





(



)

= −

(1 + 𝛽)

(4.3)

The remaining components could be computed as

above. Using the above derivations, the Ricci

curvature of the stable M/G/1 QM can be devised.

5 THE KD AND THE J-D OF

STABLE M/G/1 QM

Following (2.6), KD is expressed by

𝐾

(

𝑝,𝑞

)

= 𝐸





𝑙 𝑛





;









;





 =

⎩

⎪

⎨

⎪

⎧

𝒍𝒏(

𝟏−𝝆

𝒑

𝟏−𝝆

𝒒

), 𝒏 =𝟎

𝒍𝒏

𝟏−𝝆

𝒑

𝟏−𝝆

𝒒



𝟏+𝜷

𝒒

𝟏+𝜷

𝒑

[

𝝆

𝒒

(𝟐 + 𝝆

𝒒

(𝜷

𝒒

−𝟏)

𝝆

𝒑

(𝟐 + 𝝆

𝒑

(𝜷

𝒑

−𝟏)



𝟏+𝜷

𝒒

𝟏+𝜷

𝒑

]

𝑳

,𝒏≥𝟎

(5.1)

where 𝐿 is MQL of Pollaczeck-Khinchin Formula of

a stable M/G/1 QM. (5.1)

Moreover, in a similar fashion, it could be seen

that

𝐽

(

𝑝,𝑞

)

=𝐾

(

𝑝,𝑞

)

+𝐾

(

𝑞,𝑝

)

(5.2)

Equation (5.2) presents a great contribution as it

shows that the stable M/G/1 QM is incompressible or

non-solenoidal, in which case any closed surface has

no net flux across it.

6 THE STABLE M/G/1 QM HAS A

NON-ZERO RICCI

CURVATURE (RCT) TENSOR

In this section, it is revealed that the stable M/G/1 QM

is developable (can be mapped onto the plane surface

without distortion of curves: any curve from such a

surface drawn onto the flat plane remains the same)

and has a non-zero Ricci curvature, shortly written as

(RCT) tensor (the M/G/1 QM is more positively

curved than a sphere and the diameter of the manifold

is smaller).

Theorem 6.1. The stable M/G/1 QM.

i) Has a zero 0-Gaussian curvature ii) Has a non-zero

Ricci tensor

Proof. Case i), by definition (2.10), part i), it is

enough to show that the 𝛼−Gaussian curvature

𝐾

(



)





()











= 0

(6.1)

It could be verified that,

𝑅



()

(6.2)

𝑑𝑒𝑡



𝑔





= −



(



)



()



≠0. Hence, 𝐾

(



)





()







=0,

which proves the developability Case i) of stable

M/G/1 QM.

Case ii) To prove that the stable M/G/1 (QM)

Ricci tensor is non-zero, one needs to show that the

𝛼−RCs,𝑅



()

are given by(c.f., definition 2.8, part 2)

𝑅

𝑖𝑘

(𝛼)

= 𝑅

𝑖𝑗𝑘𝑙

(𝛼)

𝑔

𝑗𝑙

,𝑖,𝑗,𝑘,𝑙=1,2,3,….,𝑛

is non zero, which means that at least one of its

components is non-zero. By (6.1), 𝑅

(𝛼)

equals

𝑅



()

𝑔



+ 𝑅



()

𝑔



+ 𝑅



()

𝑔



+ 𝑅



()

𝑔



Engaging the same procedure as in (6.1), we have

𝑅



(



)

=𝑅



(



)

=𝑅



(



)

(6.3)

𝑅



()

=−



(



)



(6.4)

Hence,

𝑅



()

≠0

(6.5)

This proves Case ii).

The Impact of Information Geometry on the Analysis of the Stable M/G/1 Queue Manifold

157

As 𝜌→1, 𝑅



()

→−∞. This shows the significant

impact of instability of the two dimensional M/G/1

QM. This presents a novel link between Ricci

Curvature (RCT) and the stability analysis of Queueing

Systems. It is clear that 𝑅



()

is a server utilization

dependent function. To experiment more closely the

impact of the server utilization, 𝜌 and the behaviour of

the (RCT). It is observed by Figure 5 that the stability

phase of M/G/1 QM enforces (RCT) to be a decreasing

function in 𝜌, whereas in Figure 6, it can be seen that

instability phase of M/G/1 QM enforces (RCT) to be

an increasing in 𝜌.

Figure 5. Figure 6.

7 THE EXPONENTIAL MATRIX

OF FIM OF STABLE M/G/1 QM

Theorem 7.1. The exponential matrix of the Fisher

information of the stable M/G/1 QM is a solution of a

differential equation of the form





= Ax.

Proof. It has been proved earlier (c.f. Theorem 3.1)

that the FIM of the stable M/G/1 queue manifold

𝑔



,𝑖,𝑗=1,2 is given by

𝑔



= 



(



)





(



)





(7.1)

We write

[𝑔



] =



𝑎0

0 𝑏



,𝑎=





()





,𝑏=



(



)



(7.2)

It follows that

(

𝛿

)

(

𝛿

)

=det[𝑔



]−δI=

det



𝑎−𝛿 0

0 𝑏− 𝛿



. Hence, it holds that

𝛿



−

(

𝑎+𝑏

)

𝛿+𝑎𝑏 =0,

which implies that the eigenvalues

are given by

𝛿

,

=𝑎,𝑏. The diagonal matrix D is

given by

𝐷 = 

𝛿



0 𝛿





(7.3)

For

𝛿

,

=𝑎,𝑏 , the corresponding eigen vectors

are 





, 





.Hence,

T = 𝑇







(7.4)

Hence, the exponential matrix of the FIM of the

stable M/G/1 queue manifold is given by

𝑒



= 𝑇𝑒



𝑇





𝑒



0 𝑒





(7.5)

The result obtained in (7.5) shows that the

exponential of the FIM of the stable M/G/1 queue

manifold is a solution of a differential equation of the

form





= Ax

(7.6)

8 CONCLUSIONS AND FUTURE

WORK

The stable M/G/1 QM is characterized from the

viewpoint of IG, KD and J-D were determined.

Moreover, the matrix exponential of information of

the M/G/1 QM is devised. This paper opens a new

ground for research linking queueing theory with

many other mathematical disciplines such as

information theory, differential geometry and matrix

theory. Specifically, adding information geometric

links with queueing theory enables the study of the

dynamics of a queueing system from the Riemannian

Geometric point of view (c.f., Amari, 1985) and (c.f.,

Dodson, 1999) and in turn, enabling the analysis of a

queueing system based on the Theory of Relativity

(c.f., Norton, 2020).

This paper has introduced for the first time the

FIM and its inverse and has also obtained the Fisher

information metric for the M/G/1 QM.

Moreover, a novel expression for 𝛼 (or ∇

(α)

connection of the stable M/G/1 queue manifold was

devised. In addition, the KD and the J-D of the stable

M/G/1 queue manifold were devised. In this context,

it was shown that the stable M/G/1 queue manifold

can be described as compressible or non-solenoidal,

in which case any closed surface has no net flux

across it The latter, was justified by the Divergence

Theorem of (c.f., MIT Open Course Ware, 2010),

which states that the flux of a vector field across a

closed boundary curve C is equal to the integral of the

divergence over its interior. It is implied that, when

the J-D is zero, any closed surface has no net flux

across the M/G/1 QM. Moreover, it was revealed that

the stable M/G/1 QM has a zero 0-Gaussian curvature

and a non-zero Ricci Curvature Tensor. Finally, it

was proven that the exponential of the FIM of the

stable M/G/1 queue manifold is a solution of a

differential equation of the form

𝑑𝑥

𝑑𝑡

= Ax. Specifically,

the main original contributions of this paper are

summarised below.

ICORES 2021 - 10th International Conference on Operations Research and Enterprise Systems

158

• The proposed new approach to visualize queueing

systems via computational information geometry;

• The establishment of new links between queueing

theory and other mathematical disciplines such as

information geometry, matrix theory Riemannian

geometry and the theory of Relativity.

• Providing a novel link between Ricci Curvature

(RCT) and the stability analysis of the stable

M/G/1 QM.

• Having introduced several information geometric

concepts, we have managed for first time to

capture the M/G/1 queue as a manifold and

analysed the M/G/1 QM by using information

geometric methods. Consequently, classical

Queueing Theory can be extended to become

richer because of the application of IG.

An exponential family or mixture family of

probability distributions has a natural hierarchical

structure. Orthogonal decomposition of such a system

based (c.f. Amari, 2001) on information geometry. A

typical example is the decomposition of stochastic

dependency among a number of random variables. In

general, they have a complex structure of

dependencies. The orthogonal decomposition is given

in a wide class of hierarchical structures including

both exponential and mixture families. As an

example, we decompose the dependency in a higher

order Markov chain into a sum of those in various

lower order Markov chains.

Single-server, such as M/G/1 system is simple and

can be utilized as preliminary models (c.f., Hamasha

et al, 2016). Modelling of the systems state using

Markov chain approach and queuing models provides

a more rigid approach to better understand the

dynamics of the service delivery system, which

proposes a conceptual model using of Markov chain

approach combined with M/G/1 queuing model to

optimize general service delivery systems.

Based on the above discussion, clearly the lost

link is now uncovered by our novel approach as it

reveals the significant impact of IG on Queueing

Theory.

The stability problem (Rachev, 1989) in queueing

theory is concerned with the continuity of the

mapping F from the set U of the input flows into the

set V of the output flows. First, using the theory of

probability metrics we estimate the modulus of F-

continuity providing that U and V have structures of

metric spaces. Then we evaluate the error terms in the

approximation of the input flows by simpler ones

assuming that we have observed some functionals of

the empirical input flows distributions. This shows

the strength of our novel approach as it derives for the

first time ever the exact stability and instability

phases of the underlying M/G/1 queueing system.

The beauty of our novel approach that

revolutionizes Queueing Theory, is looking at a queue

as a manifold, in which case, 𝛼 is considered as the

parameter of curvature as well as being the connection

parameter of the underlying stable M/G/1 QM.

In other words, under a metric connection (c.f.,

Jefferson, 2018), parallel transport of two vectors

preserves the inner product, hence their significance

in Riemannian geometry. Any connection which is

both metric and symmetric is Riemannian, of which

there are generically an infinite number. However, the

natural metrics on statistical manifolds are

generically non-metric! Indeed, since only the special

case 𝛼=0 defines a Riemannian connection ∇

()

with respect to the Fisher metric (though observe that

∇

()

is symmetric for any value of 𝛼). While this may

seem strange from a physics perspective, where

preserving the inner product is of prime importance,

there’s nothing mathematically pathological about it.

Indeed, the more relevant condition, that every point

on the manifold have an interpretation as a probability

distribution. In general, (c.f., Lee, 1950),

exponentiating a matrix corresponds to

exponentiating each of its Jordan blocks. In fact, this

interpretation also holds for any analytic function 𝑓

applied to a matrix and not just 𝑒



. Also, it may be

useful to think of the matrix exponential as the

"Solution to the System of Ordinary Differential

Equations (ODEs)".

Based on the contributions of this paper, there are

several future research directions towards the new

applications of information geometric queueing

theory includes developing further advances on many

existing queueing manifolds, such as the G/G/1 queue

(c.f., Dodson, 2005 and Kouvatsos 1988) manifold

and employing information geometrics on various

statistical manifolds.

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