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In [[queueing theory]], a discipline within the mathematical [[probability theory|theory of probability]], an '''M/D/1 queue''' represents the queue length in a system having a single server, where arrivals are determined by a [[Poisson process]] and job service times are fixed (deterministic). The model name is written in [[Kendall's notation]].<ref>{{Cite journal | last1 = Kendall | first1 = D. G. | authorlink1 = David George Kendall| title = Stochastic Processes Occurring in the Theory of Queues and their Analysis by the Method of the Imbedded Markov Chain | doi = 10.1214/aoms/1177728975 | jstor = 2236285| journal = The Annals of Mathematical Statistics | volume = 24 | issue = 3 | pages = 338 | year = 1953| url = http://projecteuclid.org/euclid.aoms/1177728975 | pmid = | pmc = }}</ref> [[Agner Krarup Erlang]] first published on this model in 1909, starting the subject of [[queueing theory]].<ref>{{Cite journal | last1 = Kingman | first1 = J. F. C. | authorlink1 = John Kingman | title = The first Erlang century—and the next | journal = [[Queueing Systems]] | volume = 63 | pages = 3–4 | year = 2009 | doi = 10.1007/s11134-009-9147-4}}</ref><ref>{{cite journal|title=The theory of probabilities and telephone conversations |journal=Nyt Tidsskrift for Matematik B |volume=20 |pages=33–39 |first=A. K. |last=Erlang |url=http://oldwww.com.dtu.dk/teletraffic/erlangbook/pps131-137.pdf |year=1909 |deadurl=yes |archiveurl=https://web.archive.org/web/20111001212934/http://oldwww.com.dtu.dk/teletraffic/erlangbook/pps131-137.pdf |archivedate=October 1, 2011 }}</ref> An extension of this model with more than one server is the [[M/D/c queue]].
In [[queueing theory]], a discipline within the mathematical [[probability theory|theory of probability]], an '''M/D/1 queue''' represents the queue length in a system having a single server, where arrivals are determined by a [[Poisson process]] and job service times are fixed (deterministic). The model name is written in [[Kendall's notation]].<ref>{{Cite journal | last1 = Kendall | first1 = D. G. | author-link1 = David George Kendall| title = Stochastic Processes Occurring in the Theory of Queues and their Analysis by the Method of the Imbedded Markov Chain | doi = 10.1214/aoms/1177728975 | jstor = 2236285| journal = The Annals of Mathematical Statistics | volume = 24 | issue = 3 | pages = 338 | year = 1953| url = http://projecteuclid.org/euclid.aoms/1177728975 | doi-access = free }}</ref> [[Agner Krarup Erlang]] first published on this model in 1909, starting the subject of [[queueing theory]].<ref>{{Cite journal | last1 = Kingman | first1 = J. F. C. | author-link1 = John Kingman | title = The first Erlang century—and the next | journal = [[Queueing Systems]] | volume = 63 | pages = 3–4 | year = 2009 | doi = 10.1007/s11134-009-9147-4}}</ref><ref>{{cite journal|title=The theory of probabilities and telephone conversations |journal=Nyt Tidsskrift for Matematik B |volume=20 |pages=33–39 |first=A. K. |last=Erlang |url=http://oldwww.com.dtu.dk/teletraffic/erlangbook/pps131-137.pdf |year=1909 |url-status=dead |archive-url=https://web.archive.org/web/20111001212934/http://oldwww.com.dtu.dk/teletraffic/erlangbook/pps131-137.pdf |archive-date=October 1, 2011 }}</ref> An extension of this model with more than one server is the [[M/D/c queue]].


==Model definition==
==Model definition==


An M/D/1 queue is a stochastic process whose [[state space]] is the set {0,1,2,3,...} where the value corresponds to the number of customers in the system, including any currently in service.
An M/D/1 queue is a stochastic process whose [[state space]] is the set {0,1,2,3,...} where the value corresponds to the number of entities in the system, including any currently in service.


* Arrivals occur at rate λ according to a [[Poisson process]] and move the process from state ''i'' to ''i''&nbsp;+&nbsp;1.
* Arrivals occur at rate λ according to a [[Poisson process]] and move the process from state ''i'' to ''i''&nbsp;+&nbsp;1.
* Service times are deterministic time ''D'' (serving at rate ''μ''&nbsp;=&nbsp;1/''D'').
* Service times are deterministic time ''D'' (serving at rate ''μ''&nbsp;=&nbsp;1/''D'').
* A single server serves customers one at a time from the front of the queue, according to a [[first-come, first-served]] discipline. When the service is complete the customer leaves the queue and the number of customers in the system reduces by one.
* A single server serves entities one at a time from the front of the queue, according to a [[first-come, first-served]] discipline. When the service is complete the entity leaves the queue and the number of entities in the system reduces by one.
* The buffer is of infinite size, so there is no limit on the number of customers it can contain.
* The buffer is of infinite size, so there is no limit on the number of entities it can contain.

The [[state space]] diagram for M/D/1 queue is as below:

[[File:Flow_chart111.png|link=https://en.wikipedia.org/wiki/File:Flow_chart111.png|thumb|602x602px|Stage Space Diagram of M/D/1 Queue|none]]
===Transition Matrix===

The transition probability matrix for an M/D/1 queue with arrival rate λ and service time 1, such that λ <1 (for stability of the queue) is given by P as below:<ref name=":1" />


=== Transition Matrix ===
<math>P=\begin{pmatrix} a_0 & a_1 & a_2 & a_3 & ... \\ a_0 & a_1 & a_2 & a_3 & ...\\ 0 & a_0 & a_1 & a_2 & ...\\ 0&0 & a_0 & a_1 & ...\\... & ... &...&... &...\\\end{pmatrix}</math> , <math>a_n=\frac{\lambda^n}{n!}e^{-\lambda}</math>, n = 0,1,....
<math>P=\begin{pmatrix} a_0 & a_1 & a_2 & a_3 & ... \\ a_0 & a_1 & a_2 & a_3 & ...\\ 0 & a_0 & a_1 & a_2 & ...\\ 0&0 & a_0 & a_1 & ...\\... & ... &...&... &...\\\end{pmatrix}</math> , <math>a_n=\frac{\lambda^n}{n!}e^{-\lambda}</math>, n = 0,1,....


=== Classic performance metrics ===
===Classic performance metrics===

The following expressions present the classic performance metrics of a single server queuing system such as M/D/1, with:

* arrival rate <math>=\lambda</math>,
* service rate <math>=\mu</math>,&nbsp;and
* utilization <math>=\rho=\frac{\lambda}{\mu}</math>

The average number of entities in the system, L is given by:

<math>L=\rho+\frac{1}{2}\left ( \frac{\rho^2}{1-\rho} \right );
<math>L=\rho+\frac{1}{2}\left ( \frac{\rho^2}{1-\rho} \right );
</math>
</math>

The average number of entities in the queue (line), L<sub>Q</sub> is given by:


<math>L_Q=\frac{1}{2}\left ( \frac{\rho^2}{1-\rho} \right );
<math>L_Q=\frac{1}{2}\left ( \frac{\rho^2}{1-\rho} \right );
</math>
</math>

The average waiting time in the system, ω is given by:


<math>\omega= \frac{1}{\mu}+\frac{\rho}{2\mu(1-\rho)};
<math>\omega= \frac{1}{\mu}+\frac{\rho}{2\mu(1-\rho)};
</math>
</math>

The average waiting time in the queue (line), ω <sub>Q</sub> is given by:


<math>\omega_Q=\frac{\rho}{2\mu(1-\rho)}</math>
<math>\omega_Q=\frac{\rho}{2\mu(1-\rho)}</math>


=== Example ===
=== Example ===
Customers arrive a Starbucks line at a rate of 20 per hour, and follows an exponential distribution. There is only one server, the service rate is at a constant of 30 per hour.
Considering a system that has only one server, with an arrival rate of 20 entities per hour and the service rate is at a constant of 30 per hour.


So the utilization of the server is: ρ=20/30=2/3. Using the metrics shown above, the results are as following: 1) Average number in line L<sub>Q</sub>= 0.6667; 2) Average number in system L =1.333; 3) Average time in line ω<sub>Q</sub> = 0.033 hour; 4) Average time in system ω = 0.067 hour.
Arrival Rate: 20 per hour


=== Relations for Mean Waiting Time in M/M/1 and M/D/1 queues ===
Service Rate: 60 per hour
For an equilibrium M/G/1 queue, the expected value of the time W spent by a customer in the queue are given by Pollaczek-Khintchine formula as below:<ref name=":0">{{Cite book|title=Introduction to Queuing Theory|last=Cooper|first=Robert B.|publisher=Elsevier Science Publishing Co.|year=1981|isbn=0-444-00379-7|pages=189}}</ref>


<math>E(W)=\frac{\rho\tau}{2(1-\rho)}\left(1+\frac{\sigma^2}{\tau^2}\right)</math>
ρ=20/30=2/3


where τ is the mean service time; σ<sup>2</sup> is the variance of service time; and ρ=λτ < 1, λ being the arrival rate of the customers.
Using the queueing theory equations, the results are as following:


For M/M/1 queue, the service times are exponentially distributed, then σ<sup>2</sup> = τ<sup>2</sup> and the mean waiting time in the queue denoted by W<sub>M</sub> is given by the following equation:<ref name=":0" />
Average number in line= 0.6667

Average number in system: 1.333

Average time in line: 0.033 hour

Average time in system: 0.067 hour

=== Relation for Mean Waiting Time in M/M/1 and M/D/1 queues<ref>{{Cite book|title=Introduction to Queuing Theory|last=Cooper|first=Robert B.|publisher=Elsevier Science Publishing Co.|year=1981|isbn=0-444-00379-7|location=|pages=189}}</ref> ===
For an equilibrium M/G/1 queue, the expected value of the time W spent by a customer in the queue are given by Pollaczek-Khintchine formula as below:

<math>E(W)=\frac{\rho\tau}{2(1-\rho)}(1+\frac{\sigma^2}{\tau^2})</math>

where τ is the mean service time; <math display="inline">\sigma^2</math> is the variance of service time; and ρ=λτ < 1, λ being the arrival rate of the customers.

For M/M/1 queue, the service times are exponentially distributed, then <math display="inline">\sigma^2</math>=<math display="inline">\tau^2</math> and the mean waiting time in the queue denoted by W<sub>M</sub> is given by the following equation:


<math>{W_M}=\frac{\rho\tau}{1-\rho}</math>
<math>{W_M}=\frac{\rho\tau}{1-\rho}</math>


Using this, the corresponding equation for M/D/1 queue can be derived, assuming constant service times. Then the variance of service time becomes zero, i.e.  <math display="inline">\sigma^2</math>=0.  The mean waiting time in the M/D/1 queue denoted as W<sub>D</sub> is given by the following equation:
Using this, the corresponding equation for M/D/1 queue can be derived, assuming constant service times. Then the variance of service time becomes zero, i.e. σ<sup>2</sup> = 0. The mean waiting time in the M/D/1 queue denoted as W<sub>D</sub> is given by the following equation:<ref name=":0" />


<math>{W_D}=\frac{\rho\tau}{2(1-\rho)}</math>
<math>{W_D}=\frac{\rho\tau}{2(1-\rho)}</math>
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==Stationary distribution==
==Stationary distribution==


The number of jobs in the queue can be written as an [[M/G/1 queue|M/G/1 type Markov chain]] and the stationary distribution found for state ''i'' (written π<sub>''i''</sub>) in the case ''D''&nbsp;=&nbsp;1 to be<ref>{{cite journal| url = http://www.orsj.or.jp/~archive/pdf/e_mag/Vol.48_2_111.pdf | journal = Journal of the Operations Research Society of Japan | volume = 48 | year = 2005 | issue = 2 | pages = 111-122 | title = On the Series Expansion for the Stationary Probabilities of an M/D/1 queue | first = Kenji | last = Nakagawa}}</ref>
The number of jobs in the queue can be written as [[M/G/1 queue|M/G/1 type Markov chain]] and the stationary distribution found for state ''i'' (written π<sub>''i''</sub>) in the case ''D''&nbsp;=&nbsp;1 to be<ref name=":1">{{cite journal| url = http://kashiwa.nagaokaut.ac.jp/members/nakagawa/ronbun/029.pdf | journal = Journal of the Operations Research Society of Japan | volume = 48 | year = 2005 | issue = 2 | pages = 111–122 | title = On the Series Expansion for the Stationary Probabilities of an M/D/1 queue | first = Kenji | last = Nakagawa | doi=10.15807/jorsj.48.111| doi-access = free }}</ref>
:<math>\begin{align}\pi_0 &= 1-\lambda \\
:<math>\begin{align}\pi_0 &= 1-\lambda \\
\pi_1 &= (1-\lambda)(e^\lambda - 1)\\
\pi_1 &= (1-\lambda)(e^\lambda - 1)\\
Line 72: Line 75:
==Delay==
==Delay==


Define ''ρ''&nbsp;=&nbsp;''λ''/''μ'' as the utilization; then the mean delay in the system in an M/D/1 queue is<ref>{{cite book|title=Wide Area Network Design:Concepts and Tools for Optimization|page=319|first=Robert S.|last=Cahn|year=1998|publisher=Morgan Kaufmann|isbn=1558604588}}</ref>
Define ''ρ''&nbsp;=&nbsp;''λ''/''μ'' as the utilization; then the mean delay in the system in M/D/1 queue is<ref>{{cite book|title=Wide Area Network Design:Concepts and Tools for Optimization|page=319|first=Robert S.|last=Cahn|year=1998|publisher=Morgan Kaufmann|isbn=1558604588}}</ref>
::<math>\frac{1}{2\mu}\cdot\frac{2-\rho}{1-\rho}.</math>
::<math>\frac{1}{2\mu}\cdot\frac{2-\rho}{1-\rho}.</math>
and in the queue:
and in the queue:
Line 79: Line 82:
==Busy period==
==Busy period==


The busy period is the time period measured from the instant a first customer arrives at an empty queue to the time when the queue is again empty. This time period is equal to ''D'' times the number of customers served. If ''ρ''&nbsp;<&nbsp;1, then the number of customers served during a busy period of the queue has a [[Borel distribution]] with parameter ''ρ''.<ref>{{Cite journal | last1 = Tanner | first1 = J. C. | doi = 10.1093/biomet/48.1-2.222 | title = A derivation of the Borel distribution | journal = [[Biometrika]]| volume = 48 | pages = 222–224 | year = 1961 | pmid = | jstor = 2333154| pmc = }}</ref><ref>{{Cite journal | last1 = Haight | first1 = F. A. | last2 = Breuer | first2 = M. A. | doi = 10.1093/biomet/47.1-2.143 | title = The Borel-Tanner distribution | journal = [[Biometrika]]| volume = 47 | pages = 143 | year = 1960 | pmid = | pmc = | jstor = 2332966}}</ref>
The busy period is the time period measured from the instant a first customer arrives at an empty queue to the time when the queue is again empty. This time period is equal to ''D'' times the number of customers served. If ''ρ''&nbsp;<&nbsp;1, then the number of customers served during a busy period of the queue has a [[Borel distribution]] with parameter ''ρ''.<ref>{{Cite journal | last1 = Tanner | first1 = J. C. | doi = 10.1093/biomet/48.1-2.222 | title = A derivation of the Borel distribution | journal = [[Biometrika]]| volume = 48 | pages = 222–224 | year = 1961 | jstor = 2333154}}</ref><ref>{{Cite journal | last1 = Haight | first1 = F. A. | last2 = Breuer | first2 = M. A. | doi = 10.1093/biomet/47.1-2.143 | title = The Borel-Tanner distribution | journal = [[Biometrika]]| volume = 47 | pages = 143 | year = 1960 | jstor = 2332966}}</ref>


==Finite capacity==
==Finite capacity==
Line 85: Line 88:
===Stationary distribution===
===Stationary distribution===


A stationary distribution for the number of customers in the queue and mean queue length can be computed using [[probability generating function]]s.<ref>{{cite journal | last1 = Brun | first1 = Olivier | last2 =Garcia | first2 = Jean-Marie | year = 2000 | title = Analytical Solution of Finite Capacity M/D/1 Queues | journal = Journal of Applied Probability | volume = 37 | issue = 4 | pages = 1092-1098 | publisher = [[Applied Probability Trust]] | jstor = 3215497 | doi = 10.1239/jap/1014843086 | url = | format = | accessdate = }}</ref>
A stationary distribution for the number of customers in the queue and mean queue length can be computed using [[probability generating function]]s.<ref>{{cite journal | last1 = Brun | first1 = Olivier | last2 =Garcia | first2 = Jean-Marie | year = 2000 | title = Analytical Solution of Finite Capacity M/D/1 Queues | journal = Journal of Applied Probability | volume = 37 | issue = 4 | pages = 1092–1098 | publisher = [[Applied Probability Trust]] | jstor = 3215497 | doi = 10.1239/jap/1014843086 }}</ref>

<math>P_0(N)=\frac{1}{1+\rho b_{N-1}};</math>

<math>P_N(N)=1-\frac{b_{N-1}}{1+\rho b_{N-1}};</math>

<math>P_j(N)=\frac{b_{j}-b_{j-1}}{1+\rho b_{N-1}}</math>, j = 1,..., N-1.


===Transient solution===
===Transient solution===


The transient solution of an M/D/1 queue of finite capacity N, often written M/D/1/N, was published by Garcia et al in 2002.<ref>{{cite journal | last1 = Garcia | first1 = Jean-Marie | last2 = Brun | first2 = Olivier | last3 = Gauchard | first3 = David | year = 2002 | title = Transient Analytical Solution of M/D/1/N Queues | journal = Journal of Applied Probability | volume = 39 | issue = 4 | pages = 853-864 | publisher = Applied Probability Trust | jstor = 3216008}}</ref>
The transient solution of an M/D/1 queue of finite capacity N, often written M/D/1/N, was published by Garcia et al. in 2002.<ref>{{cite journal | last1 = Garcia | first1 = Jean-Marie | last2 = Brun | first2 = Olivier | last3 = Gauchard | first3 = David | year = 2002 | title = Transient Analytical Solution of M/D/1/N Queues | journal = Journal of Applied Probability | volume = 39 | issue = 4 | pages = 853–864 | publisher = Applied Probability Trust | jstor = 3216008 | doi=10.1239/jap/1037816024}}</ref>

The mean number of customers in M/D/1/N queue presented in Garcia et al. 2002 is as follows:

<math>X_N=N-\frac{\sum_{k=0}^{N-1}b_k}{1+\rho b_{N-1}};
</math>

The mean waiting time W N in the M/D/1/N queuing system presented in Garcia et al. 2002 is as follows:


<math>W_N=(N-1-\frac{\sum_{k=0}^{N-1}b_k-N}{\rho b_{N-1}})T</math>
==Application==
==Application==
Includes applications in wide area network design, where a single central processor to read the headers of the packets arriving in exponential fashion, then computes the next adapter to which each packet should go and dispatch the packets accordingly. Here the service time is the processing of the packet header and cyclic redundancy check, which are independent of the length of each arriving packets. Hence, it can be modeled as a M/D/1 queue.<ref>{{Cite book|title=Wide Area Network Design: Concepts and Tools for optimization.|last=Chan|first=Robert S.|publisher=Morgan Kaufmann Publishers Inc.|year=1998|isbn=1-55860-458-8|location=|pages=319}}</ref>
Includes applications in wide area [[network planning and design|network design]],<ref>{{cite journal|last1=Kotobi|first1=Khashayar|last2=Bilén|first2=Sven G.|title=Spectrum sharing via hybrid cognitive players evaluated by an M/D/1 queuing model|journal=EURASIP Journal on Wireless Communications and Networking|volume=2017|date=2017|pages=85 |doi=10.1186/s13638-017-0871-x|url=https://jwcn-eurasipjournals.springeropen.com/articles/10.1186/s13638-017-0871-x |access-date=2017-05-05|doi-access=free}}</ref> where a single central processor to read the headers of the packets arriving in exponential fashion, then computes the next adapter to which each packet should go and dispatch the packets accordingly. Here the service time is the processing of the packet header and cyclic redundancy check, which are independent of the length of each arriving packets. Hence, it can be modeled as a M/D/1 queue.<ref>{{Cite book|title=Wide Area Network Design: Concepts and Tools for optimization.|last=Chan|first=Robert S.|publisher=Morgan Kaufmann Publishers Inc.|year=1998|isbn=1-55860-458-8|pages=319}}</ref>


==References==
==References==
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{{DEFAULTSORT:M D 1 queue}}
{{DEFAULTSORT:M D 1 queue}}
[[Category:Stochastic processes]]
[[Category:Single queueing nodes]]
[[Category:Single queueing nodes]]

Latest revision as of 14:59, 20 December 2023

In queueing theory, a discipline within the mathematical theory of probability, an M/D/1 queue represents the queue length in a system having a single server, where arrivals are determined by a Poisson process and job service times are fixed (deterministic). The model name is written in Kendall's notation.[1] Agner Krarup Erlang first published on this model in 1909, starting the subject of queueing theory.[2][3] An extension of this model with more than one server is the M/D/c queue.

Model definition

[edit]

An M/D/1 queue is a stochastic process whose state space is the set {0,1,2,3,...} where the value corresponds to the number of entities in the system, including any currently in service.

  • Arrivals occur at rate λ according to a Poisson process and move the process from state i to i + 1.
  • Service times are deterministic time D (serving at rate μ = 1/D).
  • A single server serves entities one at a time from the front of the queue, according to a first-come, first-served discipline. When the service is complete the entity leaves the queue and the number of entities in the system reduces by one.
  • The buffer is of infinite size, so there is no limit on the number of entities it can contain.


Transition Matrix

[edit]

The transition probability matrix for an M/D/1 queue with arrival rate λ and service time 1, such that λ <1 (for stability of the queue) is given by P as below:[4]

, n = 0,1,....

Classic performance metrics

[edit]

The following expressions present the classic performance metrics of a single server queuing system such as M/D/1, with:

  • arrival rate ,
  • service rate , and
  • utilization

The average number of entities in the system, L is given by:

The average number of entities in the queue (line), LQ is given by:

The average waiting time in the system, ω is given by:

The average waiting time in the queue (line), ω Q is given by:

Example

[edit]

Considering a system that has only one server, with an arrival rate of 20 entities per hour and the service rate is at a constant of 30 per hour.

So the utilization of the server is: ρ=20/30=2/3. Using the metrics shown above, the results are as following: 1) Average number in line LQ= 0.6667; 2) Average number in system L =1.333; 3) Average time in line ωQ = 0.033 hour; 4) Average time in system ω = 0.067 hour.

Relations for Mean Waiting Time in M/M/1 and M/D/1 queues

[edit]

For an equilibrium M/G/1 queue, the expected value of the time W spent by a customer in the queue are given by Pollaczek-Khintchine formula as below:[5]

where τ is the mean service time; σ2 is the variance of service time; and ρ=λτ < 1, λ being the arrival rate of the customers.

For M/M/1 queue, the service times are exponentially distributed, then σ2 = τ2 and the mean waiting time in the queue denoted by WM is given by the following equation:[5]

Using this, the corresponding equation for M/D/1 queue can be derived, assuming constant service times. Then the variance of service time becomes zero, i.e. σ2 = 0. The mean waiting time in the M/D/1 queue denoted as WD is given by the following equation:[5]

From the two equations above, we can infer that Mean queue length in M/M/1 queue is twice that in M/D/1 queue.

Stationary distribution

[edit]

The number of jobs in the queue can be written as M/G/1 type Markov chain and the stationary distribution found for state i (written πi) in the case D = 1 to be[4]

Delay

[edit]

Define ρ = λ/μ as the utilization; then the mean delay in the system in M/D/1 queue is[6]

and in the queue:

Busy period

[edit]

The busy period is the time period measured from the instant a first customer arrives at an empty queue to the time when the queue is again empty. This time period is equal to D times the number of customers served. If ρ < 1, then the number of customers served during a busy period of the queue has a Borel distribution with parameter ρ.[7][8]

Finite capacity

[edit]

Stationary distribution

[edit]

A stationary distribution for the number of customers in the queue and mean queue length can be computed using probability generating functions.[9]

Transient solution

[edit]

The transient solution of an M/D/1 queue of finite capacity N, often written M/D/1/N, was published by Garcia et al. in 2002.[10]

Application

[edit]

Includes applications in wide area network design,[11] where a single central processor to read the headers of the packets arriving in exponential fashion, then computes the next adapter to which each packet should go and dispatch the packets accordingly. Here the service time is the processing of the packet header and cyclic redundancy check, which are independent of the length of each arriving packets. Hence, it can be modeled as a M/D/1 queue.[12]

References

[edit]
  1. ^ Kendall, D. G. (1953). "Stochastic Processes Occurring in the Theory of Queues and their Analysis by the Method of the Imbedded Markov Chain". The Annals of Mathematical Statistics. 24 (3): 338. doi:10.1214/aoms/1177728975. JSTOR 2236285.
  2. ^ Kingman, J. F. C. (2009). "The first Erlang century—and the next". Queueing Systems. 63: 3–4. doi:10.1007/s11134-009-9147-4.
  3. ^ Erlang, A. K. (1909). "The theory of probabilities and telephone conversations" (PDF). Nyt Tidsskrift for Matematik B. 20: 33–39. Archived from the original (PDF) on October 1, 2011.
  4. ^ a b Nakagawa, Kenji (2005). "On the Series Expansion for the Stationary Probabilities of an M/D/1 queue" (PDF). Journal of the Operations Research Society of Japan. 48 (2): 111–122. doi:10.15807/jorsj.48.111.
  5. ^ a b c Cooper, Robert B. (1981). Introduction to Queuing Theory. Elsevier Science Publishing Co. p. 189. ISBN 0-444-00379-7.
  6. ^ Cahn, Robert S. (1998). Wide Area Network Design:Concepts and Tools for Optimization. Morgan Kaufmann. p. 319. ISBN 1558604588.
  7. ^ Tanner, J. C. (1961). "A derivation of the Borel distribution". Biometrika. 48: 222–224. doi:10.1093/biomet/48.1-2.222. JSTOR 2333154.
  8. ^ Haight, F. A.; Breuer, M. A. (1960). "The Borel-Tanner distribution". Biometrika. 47: 143. doi:10.1093/biomet/47.1-2.143. JSTOR 2332966.
  9. ^ Brun, Olivier; Garcia, Jean-Marie (2000). "Analytical Solution of Finite Capacity M/D/1 Queues". Journal of Applied Probability. 37 (4). Applied Probability Trust: 1092–1098. doi:10.1239/jap/1014843086. JSTOR 3215497.
  10. ^ Garcia, Jean-Marie; Brun, Olivier; Gauchard, David (2002). "Transient Analytical Solution of M/D/1/N Queues". Journal of Applied Probability. 39 (4). Applied Probability Trust: 853–864. doi:10.1239/jap/1037816024. JSTOR 3216008.
  11. ^ Kotobi, Khashayar; Bilén, Sven G. (2017). "Spectrum sharing via hybrid cognitive players evaluated by an M/D/1 queuing model". EURASIP Journal on Wireless Communications and Networking. 2017: 85. doi:10.1186/s13638-017-0871-x. Retrieved 2017-05-05.
  12. ^ Chan, Robert S. (1998). Wide Area Network Design: Concepts and Tools for optimization. Morgan Kaufmann Publishers Inc. p. 319. ISBN 1-55860-458-8.