Classifications

• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
  • H04L45/00—Routing or path finding of packets in data switching networks
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04J—MULTIPLEX COMMUNICATION
  • H04J14/00—Optical multiplex systems
  • H04J14/02—Wavelength-division multiplex systems
  • H04J14/0227—Operation, administration, maintenance or provisioning [OAMP] of WDM networks, e.g. media access, routing or wavelength allocation
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04J—MULTIPLEX COMMUNICATION
  • H04J14/00—Optical multiplex systems
  • H04J14/02—Wavelength-division multiplex systems
  • H04J14/0227—Operation, administration, maintenance or provisioning [OAMP] of WDM networks, e.g. media access, routing or wavelength allocation
  • H04J14/0241—Wavelength allocation for communications one-to-one, e.g. unicasting wavelengths
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
  • H04L45/00—Routing or path finding of packets in data switching networks
  • H04L45/12—Shortest path evaluation
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
  • H04L45/00—Routing or path finding of packets in data switching networks
  • H04L45/62—Wavelength based
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04J—MULTIPLEX COMMUNICATION
  • H04J14/00—Optical multiplex systems
  • H04J14/02—Wavelength-division multiplex systems
  • H04J14/0278—WDM optical network architectures
  • H04J14/0284—WDM mesh architectures

Definitions

• optical transmission systems In the course of the rapid growth of the Internet, the need for available transmission bandwidth has increased disproportionately in recent years.
• the transparent optical transmission systems are of particular importance here, as they enable complete transmission of data signals in the optical range, ie without opto-electrical or electro-optical conversion of the data signals.
• Transparent optical transmission systems are made up of a plurality of optical network nodes connected to one another via optical transmission links.
• optical wavelength channels are provided for the transmission of the optical data signals, in particular of optical WDM signals.
• Such a transparent optical transmission system enables the establishment of optical connections between two subscribers, with a selected connection path through the transparent optical transmission system as well as a wavelength channel which is available on this connection path being assigned to each optical connection.
• a connection path with a continuously available wavelength channel is determined, via which the connection can be established.
• the determined wavelength channel is occupied on all optical transmission paths of the connection path and is therefore no longer available for further connection requests.
• the current network utilization ie the occupancy of all wavelength channels on the different optical transmission links of the transparent optical transmission system.
• the following criteria should meet a good solution to the dynamic RWA problem: the lowest possible blocking probability for the current, but also for all future connection requirements; - The greatest possible efficiency of the solution.
• the dynamic RWA problem is solved, for example, by first connecting a connection path and then an available one on the selected connection path, i.e. unused wavelength channel is determined.
• a wavelength channel can first be selected within the transparent optical transmission system and then a suitable connection path to it can be determined. first connection path, then wavelength channel
• first-fit The wavelength channels are ordered arbitrarily, i.e. provided with an index. The connection path on which the wavelength channel with the smallest possible index is still unoccupied is then selected for establishing the connection.
• connection path
• the RWA problem is first reformulated here by converting the transparent optical transmission system, which consists of a large number of connection paths, in particular WDM connection paths, into a number of virtual optical sub-transmission networks of the same structure, each of these virtual optical sub-networks Transmission networks exactly one wavelength channel is assigned (see Figure 2). Each transmission link in one of the virtual optical sub-transmission networks can be used by at most one connection. These virtual optical sub-transmission networks are not connected to one another, ie there is no wavelength conversion within the virtual optical sub-transmission networks. The subscriber line devices are connected to all virtual optical sub-transmission networks. The RWA problem now consists in finding a connection path in the resulting optical transmission system, the wavelength channel already being determined by the selected virtual optical sub-transmission network.
• the individual virtual optical sub-transmission networks are examined in succession, for example using the “Dijkstra algorithm”, to determine whether one of the conditions mentioned above sufficient connection path to establish a connection between the two participants is available.
• the first connection path found in one of the virtual optical sub-transmission networks is used for establishing the connection.
• the following heuristics are suggested for the order in which the different virtual optical sub-transmission networks are examined:
• a disadvantage in the heuristics "fixed” and “pack” may be a connection path that uses an inexpensive wavelength channel, but whose connection path is disproportionately long, ie occupies a large number of resources within the transparent optical transmission system.
• the shortest connection path is always selected in the heuristic "exhaustive", even if the assigned wavelength channel is unfavorable, even though there would be an only insignificantly longer connection path with a much cheaper wavelength channel.
• favorable wavelength channels are to be understood as wavelength channels which are already frequently used in the optical transmission system under consideration. These should be used even more often to reduce blocking rates, so that other wavelength channels are not used.
• the object of the present invention is to be seen in providing an improved method for determining a connection path and a wavelength channel which is not occupied on the optical transmission paths of the connection path for establishing a connection within a transparent optical transmission system, which has a low blocking rate and a small resource consumption within the optical Transmission system enables.
• connection path and a wavelength channel not occupied on the optical transmission paths of this connection path for establishing a connection via at least a first and second network node within a transparent optical transmission system with a large number of further network nodes connected to one another via optical transmission paths is included therein see that in each case a link weight dependent on the optical transmission link and the wavelength channel under consideration is determined for the wavelength channels of an optical transmission link.
• a connection cost value is then formed for each connection path available for the connection establishment and the associated wavelength channel by evaluating the at least one link weight, and the connection path having the minimum connection cost value and the associated wavelength channel is selected for establishing the connection.
• the two criteria of favorable wavelength and the properties of the optical transmission link are advantageously taken into account together in a link weight dependent on these criteria when determining the connection path and an associated wavelength channel.
• Wavelength channels of a transmission link for example, are assigned a link weight with the value infinite.
• a connection cost value is formed from the determined link weights of a connection path and the associated wavelength channel, which indicates the costs or the resources required for establishing the connection via the connection path and wavelength channel under consideration. Starting from the connection cost values formed, the connection path having a minimum connection cost value and the associated wavelength channel is selected for the connection establishment. This avoids the disadvantages of the methods known from the prior art, in particular the high computing effort required for determining the connection path, including the wavelength channel.
• Another advantage of the method according to the invention can be seen in the fact that a network-wide channel weight is assigned to each wavelength channel and the network-wide channel weight is determined with the aid of a channel weight function. As a result, a network-wide channel weight that can be determined using simple technical means is determined particularly advantageously.
• the transparent optical transmission system is advantageously divided into a number of virtual optical sub-transmission networks each having only one optical wavelength channel, the link weights according to the invention being assigned to the transmission links present in the sub-transmission networks and for determining the connection path and having the minimum connection cost value of the associated wavelength channel, the sub-transmission networks are evaluated.
• the link weights according to the invention are assigned to the transmission links present in the sub-transmission networks and for determining the connection path and having the minimum connection cost value of the associated wavelength channel, the sub-transmission networks are evaluated.
• the channel weight function represents a function dependent on the respective wavelength channel, advantageous embodiments being proposed according to the invention.
• the channel weight function can, for example, be a linear radio that is dependent on the respective wavelength channel
• the channel weight function can take into account the occupancy state of the wavelength channels on the transmission links already occupied by further connections. To this end, the current utilization rate of each wavelength channel is determined or estimated within the transparen ⁇ th optical transmission system.
• a monotonically decreasing function g () has the advantage that already be ⁇ frequently used wavelength channels are vorzugt account when determining a required for the establishment of a new connection path connection and the associated wavelength channel.
• FIG. 1 shows, by way of example, a schematic illustration of a transparent optical transmission system
• FIG. 2 shows a schematic illustration of the transparent optical transmission system converted into a plurality of virtual optical sub-transmission systems
• FIG. 3 shows a schematic illustration of the assignment of the link weights according to the invention within the virtual optical sub-transmission systems
• FIG. 4 shows a schematic illustration of the occupancy states of a transparent optical transmission system with three wavelength channels.
• FIG. 1 shows a transparent optical transmission system ASTN (here: an automatically switched transport network) that has a large number of network nodes A, B, C, D, E, F connected to one another via optical transmission links OS1 to 0S9 , Furthermore, subscriber connection devices, in particular a first and second client device C1, C2, are shown as examples, which are connected to at least one of the network nodes A, B, C, D, E, F of the transparent optical transmission system ASTN.
• a first to sixth network node A to F are provided, the first network node A being connected to the second network node B via a first optical transmission link OS1 and to the third network node C via a second optical transmission link 0S2.
• the second network node B in turn is connected to the third network node C via a third optical transmission link 0S3 and to the fourth network node D via a fourth optical transmission link 0S4. Furthermore, the third network node C is connected via a fifth optical transmission link 0S5 to the fourth network node D and via a sixth optical transmission link 0S6 to the fifth network node E, which is connected to the fourth network node D via a seventh optical transmission link 0S7 and via an eighth optical transmission link 0S8 is connected to the sixth network node F.
• the fourth and sixth network nodes D, F are connected to one another via a ninth optical transmission link 0S9.
• first client device C1 is connected to the first network node A via a first connecting line ANL1 and the second client device C2 is connected to the sixth network node F via a second connecting line ANL2.
• WDM Wavelength Division Multiplex or Wavelength Multiplex
• WDM Wavelength Division Multiplex or Wavelength Multiplex
• the optical transmission paths OS1 to OS9 - which are constructed, for example, from an optical fiber bundle or from one or more individual optical fibers, each have a plurality of wavelength channels wkl to wkn, the number of wavelength channels wkl to wkn being able to vary from optical transmission path to optical transmission path.
• the transmission of the optical signals os takes place via one of the first to nth wavelength channels wkl to wkn after the connection has been established between the first and second client devices C1, C2.
• each of the first to ninth optical transmission links OS1 to OS9 has n wavelength channels wkl to wkn.
• the transparent optical transmission system ASTN shown in FIG. 1 is converted into a number of virtual optical sub-transmission networks Subl to Subn each having only one optical wavelength channel wkl to wkn, each virtual optical sub-transmission network Subl to Subn each having a wavelength channel wkl to wkn assigned to the network.
• FIG. 2 is a schematic illustration of the transparent optical transmission system ASTN of FIG. 1, for example after the transfer into a first, second to nth virtual optical sub-transmission network Subl to Subn shown, wherein within the first virtual sub-transmission network Subl the first wavelength channel wkl is provided for the transmission of the optical signals os on the optical transmission paths OS1 to OS9.
• the second wavelength channel wk2 is provided within the second virtual sub-transmission network Sub2 and the n-th wavelength channel wkn is provided for transmitting the optical signals os within the nth virtual sub-transmission network Subn.
• the intervening virtual optical sub-transmission networks Sub3 to Subn-1 are indicated by a dotted line.
• Such a schematic representation clarifies the reformulation of the dynamic RWA problem to its simplified solution.
• suitable connection paths with unoccupied wavelength channels wkl to wkn can be determined for the desired connection setup.
• the virtual optical sub-transmission networks Subl to Subn each have the same structure as the original optical transmission system ASTN, i.e. the same number of network nodes A to F and the same number of optical transmission links OS1 to 0S9.
• the individual virtual optical sub-transmission networks Subl to Subn are not connected to one another, ie the optical transmission system ASTN under consideration has no wavelength converters.
• the individual sub-transmission networks Subl to Subn are each connected to the first and second client devices Cl, C2 via exactly one network node A, F.
• each optical transmission link OS1 to 0S9 is assigned a link weight d r , which corresponds to the position parameter d r in the exemplary embodiment under consideration.
• the same link weight d r is assigned to each optical transmission link OS1 to 0S9 within the virtual optical sub-transmission networks Subl to Subn, ie in the first sub-transmission network Subl the first optical transmission link OS1 has the same link weight d L as, for example, within the second virtual optical sub-transmission - network Sub2.
• the index r indicates the number of the optical transmission link OS1 to OS9.
• FIG. 3 the first step of the method according to the invention is explained on the basis of the layer model already shown in FIG.
• the supply networks in n virtual optical Sububertra- Subl to Subn transferred optical transmission system ASTN is by means of a suitable search algorithm, such as the di kstra algorithm, then examined under ⁇ whether the required for the connection setup framework having Direction communication path between, for example, the first and second client devices Cl, C2 is present.
• a link weight d i; L which is dependent on the optical transmission link and on the wavelength channel under consideration is determined individually for each optical transmission link OS1 to 0S9 and each wavelength channel wkl to wkn of the optical transmission system ASTN, ie each optical transmission link OS1 to 0S9
• a link weight d_, which is dependent on the considered wavelength channel wkl to wkn and on the properties of the optical transmission link OS1 to 0S9, is assigned to the virtual optical sub-transmission networks Subl to Subn.
• the new link weight d 1 # r per transmission link OS1 to OS9 and wavelength channel wkl to wkn is determined according to the following formula:
• the index I of the link weight d ,, r denotes the number I of the wavelength channel wkl to wkn and the index r the number r the transmission path OS1 to OS9.
• the link weight d l ⁇ r ⁇ rd is formed according to the formula from the product of a channel weight function f (1) and the position parameter d r .
• the link weight d 1> r is thus composed of a position parameter d r taking into account the position r in the original transparent optical transmission system ASTN and a channel weight e- dependent on the respective wavelength channel wknl to wkn. together.
• the channel weight e x denotes the value of the channel weight function f ( ⁇ ) for the wavelength channel wkl to wkn with index I.
• the channel weight e is determined network-wide using the channel weight function fd) and assigned to the associated virtual optical sub-transmission network Subl to Subn.
• the link weights d ⁇ , r determined are each shown as the product of the network-wide channel weight e and the location parameter d, and are assigned to the associated optical transmission links OS1 to OS9 in the individual virtual optical sub-transmission network Subl to Subn.
• the first virtual optical sub-transmission network Subl has link weights d_, L , which are shown as the product of the first network-wide channel weight ei and the associated position parameter d.
• the second to nth virtual optical sub-transmission network Subn have link weights ar , each of which is a product of the second to nth network-wide channel weight e; to e n and the respective associated storage parameter d L are realized.
• a channel weight function f ( ⁇ ) which is dependent on the respective wavelength channel wkl to wkn is formed.
• Such a channel weight function f ( ⁇ ) can be a function of the shape which is linearly dependent on the respective wavelength channel wkl to wkn
• the channel weight function f ( ⁇ ) can alternatively take into account the state of occupancy of the wavelength channels wkl to wkn on the optical transmission links OS1 to OS9 already occupied by connections, the current degree of use of each optical wavelength channel wkl to wkn being determined within the transparent optical transmission system ASTN or is estimated.
• any function any function.
• FIG. 4 shows the advantages of the proposed method using the example of the transparent optical transmission system ASTN considered with a first, second and third world.
• lenlength channel wkl to wk3 per optical transmission path OSl to OS9 explained.
• the second client device C2 is connected to the fourth network node D via the second connecting line ANL2.
• a suitable connection path VP and an associated wavelength channel wkl to wk3 are determined for establishing a connection between the first and second client devices C1, C2.
• the first to third wavelength channels wkl to wk3 of the first to ninth optical transmission links OS1 to OS9 have the following assignments, with a logical 0 denoting the wavelength channel wkl to wk3 under consideration and a logical 1 denoting the unoccupied one Wavelength channel wkl to wk3 designated:
• the three wavelength channels of this example are equivalent in their transmission characteristics, and their arrangement is arbitrary.
• wkl to wk3 are in accordance with the occupancy states of the first to third wavelength channels A first, second and a third connection path VP1, VP2, VP3 are possible for the optical transmission paths OS1 to OS9.
• the first connection path VP1 runs from the first network node A via the first optical transmission link OS1 to the second network node B and from there via the third optical transmission link OS3 to the third network node C. From the third network node C, the first connection path VPl continues via the sixth optical transmission link 0S6 fifth network node E and from this in turn via the eighth optical transmission link 0S8 to the sixth network node F. Finally, the first connection path leads from the sixth network node F via the ninth optical transmission link 0S9 to the fifth network node D.
• the first connection path VP1 thus runs over five optical transmission links OSl, OS3, OS6, OS8, OS9.
• the first wavelength channel wkl is still unoccupied on the first connection path VP1 and is therefore available for the planned connection establishment.
• the second connection path VP2 runs from the first network node A via the second optical transmission link OS2 to the third network node C and from there via the third optical transmission link OS3 to the second network node B. From the second network node B the second connection path VP2 leads via the fourth optical transmission link OS4 to the fourth Network node D.
• the second connection path VP2 has three optical transmission links 0S2, OS3, 0S4, the second wavelength channel wk2 being available for establishing the connection
• the third connection path VP3 also leads from the first network node A via the first optical transmission link OS1 to the second network node B and from there via the third optical transmission link OS3 to the third network node C.
• the last section of the third connection path VP3 runs from the third network node C via the fifth optical node Transmission path OS5 to the fourth network node D.
• the third connection path VP3 has three optical transmission links OS1, OS3, 0S5, on each of which the third wavelength channel wk3 is unoccupied and is therefore available for establishing a connection.
• connection paths VP1 to VP3 with different lengths, i.e. Number of optical transmission links OS1 to OS9. These three connection paths VP1 to VP3 are compared in the table below.
• this table contains the degree of utilization of the respective virtual optical sub-transmission network Subl to Sub3.
• the second connection path VP2 is the cheapest choice for establishing the connection between the first and second client devices C1, C2.
• the second connection path VP2 is significantly shorter than the first connection path VP1, and the associated second sub-transmission network Sub2 has a higher degree of utilization h than the third connection path VP3 having the same length 1.
• f (i) (l-bi).
• connection costs (l-b ⁇ ) -l also listed in Table 2. Both examples with different channel weight functions each deliver the second connection path VP2 as a connection path with the lowest connection costs.
• the heuristic "pack” differs from “fixed” only in that the order of the wavelength channels wkl to wk3 is not fixed, but depends on the degree of utilization i. In the present example, however, this order is the same as for "fixed” and the heuristic "pack” thus also supplies the unfavorable first connection path VP1.
• a serious disadvantage of the heuristic "exhaustive” only becomes apparent in optical transmission systems which are larger and thus more complex than the exemplary embodiment shown.
• the heuristic "exhaustive” then delivers the shorter connection path, which is, however, significantly less favorable than the slightly longer one
• connection path allows a compromise between the two criteria of short length and favorable wavelength channel.
• the proposed method can be used for both directional and non-directional connection paths.

Landscapes

• Engineering & Computer Science (AREA)
• Computer Networks & Wireless Communication (AREA)
• Signal Processing (AREA)
• Optical Communication System (AREA)
• Data Exchanges In Wide-Area Networks (AREA)

Applications Claiming Priority (2)

Publications (1)

Family

ID=34088806

Family Applications (1)

Country Status (5)

Families Citing this family (20)

Family Cites Families (7)

• 2003
  • 2003-07-24 DE DE10333805.5A patent/DE10333805B4/de not_active Expired - Lifetime
• 2004
  • 2004-07-13 US US10/565,684 patent/US20060188252A1/en not_active Abandoned
  • 2004-07-13 WO PCT/EP2004/051477 patent/WO2005011170A1/de active Search and Examination
  • 2004-07-13 EP EP04766208A patent/EP1649625A1/de not_active Withdrawn
  • 2004-07-13 CN CNA2004800214077A patent/CN1830167A/zh active Pending

Non-Patent Citations (1)

Also Published As

Similar Documents

Legal Events