Reoptimization of Dynamic Flexgrid Optical Networks After Link Failure Repairs

M. Żotkiewicz; M. Ruiz; M. Klinkowski; M. Pióro; L. Velasco

doi:10.1364/JOCN.7.000049

Journal of Optical Communications and Networking
Vol. 7,
Issue 1,
pp. 49-61
(2015)
•https://doi.org/10.1364/JOCN.7.000049

Reoptimization of Dynamic Flexgrid Optical Networks After Link Failure Repairs

M. Żotkiewicz, M. Ruiz, M. Klinkowski, M. Pióro, and L. Velasco

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M. Żotkiewicz, M. Ruiz, M. Klinkowski, M. Pióro, and L. Velasco, "Reoptimization of Dynamic Flexgrid Optical Networks After Link Failure Repairs," J. Opt. Commun. Netw. 7, 49-61 (2015)

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About this Article
History
- Original Manuscript: April 14, 2014
- Revised Manuscript: September 30, 2014
- Manuscript Accepted: November 24, 2014
- Published: December 23, 2014

Abstract

In dynamic flexgrid optical networks, the usage of capacity may not be optimal due to the permanent process of setting up and tearing down connections, which, if not controlled, leads to spectrum fragmentation and, as a result, to increase of connection blocking. On top of this, a restoration mechanism that is launched in reaction to a link failure (cable cut) restores the affected lightpaths. Eventually, when the cable is repaired and its capacity becomes available for new connections, the unbalance between lightly and heavily loaded links increases, thus further decreasing the probability of finding optical paths with continuous and contiguous spectrum for future connection requests. In this paper we study the effects of reoptimizing the lightpath connections after a link failure has been repaired [namely, the after-failure-repair optimization (AFRO) problem] as an effective way for both reducing and balancing capacity usage and, by these means, for improving network performance. To solve AFRO a column generation decomposition method is presented. Illustrative numerical results show that AFRO allows us to significantly decrease the request blocking probability in realistic dynamic network scenarios. Moreover, the proposed column generation algorithm delivers quasi-optimal solutions in reasonable times. Besides, traffic disruptions resulting from lightpath rerouting are practically negligible. Finally, we show that it is sufficient to apply AFRO only for a selected set of link failures in order to achieve high network performance.

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Objects and Parameters
$V$	set of nodes, $V = \| V \|$
$E$	set of links, $E = \| E \|$
$s (e)$	source node of link $e$
$t (e)$	termination node of link $e$
$e^{r}$	recently repaired link, $e^{r} \in E$
$S$	set of spectrum slices, $S = \| S \|$
$C$	set of frequency slots, $C = \| C \| = \frac{S (S + 1)}{2}$
$S (c)$	set of (contiguous) slices composing slot $c \in C$
$n (c)$	number of slices used by slot $c \in C$
$b (n)$	bit rate carried in a slot consisting of $n$ slices
$D$	set of demands, $D = \| D \|$
$s (d)$	source node of demand $d$
$t (d)$	termination node of demand $d$
$h (d)$	bit rate of demand $d \in D$
$n (d)$	number of slices required to carry $h (d), d \in D$
$p (d)$	current lightpath used by demand $d \in D$
$C (d) \subseteq C$	set of slots allowable for demand $d \in D$ , $c \in C (d) \Leftrightarrow n (d) \leq n (c)$
$P (d)$	set of lightpaths (new and current) allowable for demand $d \in D$
$P = ⋃_{d \in D} P (d)$	set of all allowable lightpaths
$Q (d, e, s) \subseteq P (d)$	set of lightpaths for $d \in D$ using slice $s \in S$ on link $e \in E$
$Q (d, e) \subseteq P (d)$	set of lightpaths for $d \in D$ using link $e \in E$
$E (p)$	set of links traversed by lightpath $p \in P$
$d (p)$	demand $d \in D$ realized by lightpath $p \in P$
$c (p)$	slot occupied by lightpath $p \in P$ , $c (p) \in C (d)$
$n (p) = n (c (p))$	number of slices occupied by lightpath $p \in P$
$L (p)$	cost of lightpath $p$ , $L (p) = \| E (p) \| \cdot n (p)$
$H (p)$	highest index of any slice used by lightpath $p$ , $1 \leq H (p) \leq S$
$S (p) = S (c (p))$	set of slices used by lightpath $p \in P$
$κ_{e s}$	cost of using slice $s$ in link $e$
$K$	set of different sizes of demands in terms of a number of requested slices
$n (k)$	number of requested slices for demand size $k \in K$
Problem Variables
$x_{d p}, d \in D, p \in P (d)$	binary variables, $x_{d p} = 1$ when lightpath $p$ carries its demand $d$
$z_{e}, e \in E$	integer variables, maximum index of any used slice in link $e$

Topology	Nodes	Links	Total Link Length [km]	Av. No. of Cuts per Year	MTTF [ $h$ ]	MTTR [ $h$ ]
BT	22	35	5145	$\sim 14$	625	12
EON	28	41	25,625	$\sim 70$	125	12

		Link Usage						Link Entropy
Scenario		$t 0$		$t 2$		$t 3$		$t 0$		$t 2$		$t 3$
Network	Formulation	av.	max.	av.	max.	av.	max.	av.	max.	av.	max.	av.	max.
BT	MIN-SUM	79.40	226.04	81.22	231.92	79.31	227.56	1.0755	1.7355	1.0543	1.7506	1.0519	1.7307
BT	MIN-MAX	79.40	226.04	81.22	231.72	81.18	231.04	1.0755	1.7355	1.0541	1.7465	1.0435	1.7386
EON	MIN-SUM	77.97	215.68	79.76	229.33	77.87	219.60	1.1232	1.7427	1.1034	1.7500	1.0930	1.7302
EON	MIN-MAX	77.97	215.68	79.75	229.36	79.63	228.36	1.1232	1.7427	1.1063	1.7500	1.1011	1.7450

Network	Demand Selection Strategy	$\| D^{'} \|$	$\| P \|$	$\| P^{r} \|$	Link Entropy	Gap [%]	$T [s]$
BT	full	255.28	723.90	13.12	1.0520	0.021	21.567
	complete	226.75	717.86	13.08	1.0516	1.010	21.686
	reduced	45.58	747.18	13.07	1.0520	0.021	22.458
EON	full	263.53	645.43	13.37	1.0928	0.027	15.946
	complete	238.14	639.62	13.12	1.0934	0.023	15.636
	reduced	43.48	625.43	13.16	1.0928	0.025	15.404

Network	Disruption-Aware CG	Rerouted Lightpaths	Number of Disruptions	Number of Bundles
BT	No	13.40	2.29	2.15
BT	Yes	14.19	0.47	2.49
EON	No	13.18	2.89	2.36
EON	Yes	13.51	0.26	2.52

Scenario			% of Restored Connections
Network	HT	HT/MTTF	w/o AFRO	AFRO
BT	4	4.6	99.58	99.65
EON	1.5	8.7	99.48	99.52

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Journal of Optical Communications and Networking