Brief cwdm dwdm
6
Hybrid DWDM/CWDM Optical Networks Cost-effective capacity growth and investment protection with WaveReady hybrid systems. WaveReady™ Hybrid CWDM-DWDM Optical Networks JDS Uniphase WaveReady 3000 series optical modules offer a simple, plug-and-play option for creating hybrid systems of DWDM channels interleaved with existing CWDM channel plans. Support for hybrid configurations is a key value of the WaveReady product family. CWDM is an excellent, cost-effective, first step solution for scaling metro networks. Low cost WaveReady CWDM transport can support up to eight channels at 2.5 Gb/s. This is sufficient for many networks in the metro space. If capacity needs grow beyond eight channels, WaveReady products can be used to merge DWDM and CWDM traffic seamlessly at the optical layer. This allows carriers to add many channels to networks originally designed for the more limited CWDM capacity and reach. Hybrid networks deliver true pay-as- you-grow capacity growth and investment protection. For carriers, the major advantages of hybrid CWDM/DWDM are: • Reduced cost: CWDM has a significant cost advantage over DWDM due to the lower cost of lasers and the filters used in CWDM modules. Coarse channel spacing allows more tolerance for channel deviations or wavelength deviations. Therefore, CWDM transmitters and filters are easier, and cheaper, to manufacture. This cost saving becomes quite significant for large deployments. • Pay-as-you-grow: Adding new channels one at a time allows for on-demand service introduction with minimal initial investment, a critical feature in times of reduced OPEX and CAPEX spending • Investment protection: Although 8 channels may be enough in an initial deployment, it’s important to have an upgrade path to avoid a forklift upgrade to DWDM when growth in demand finally requires significant new capacity. Given the unique WaveReady upgrade capability, carriers no longer have to choose between CWDM and DWDM—both options can be deployed simultaneously or as part of a planned future, or incremental, upgrade. WaveReady 3000 series CWDM/DWDM modules can be used in either the WaveReady 3500, usually in central offices, or in the WaveReady 3100, usually on customer premises. Current capital investment can always be used in the upgraded network.
Transcript of Brief cwdm dwdm
Hybrid DWDM/CWDM Optical Networks Cost-effective capacity growth and investment protection with WaveReady hybrid systems. WaveReady™ Hybrid CWDM-DWDM Optical Networks JDS Uniphase WaveReady 3000 series optical modules offer a simple, plug-and-play option for creating hybrid systems of DWDM channels interleaved with existing CWDM channel plans. Support for hybrid configurations is a key value of the WaveReady product family. CWDM is an excellent, cost-effective, first step solution for scaling metro networks. Low cost WaveReady CWDM transport can support up to eight channels at 2.5 Gb/s. This is sufficient for many networks in the metro space. If capacity needs grow beyond eight channels, WaveReady products can be used to merge DWDM and CWDM traffic seamlessly at the optical layer. This allows carriers to add many channels to networks originally designed for the more limited CWDM capacity and reach. Hybrid networks deliver true pay-as-you-grow capacity growth and investment protection. For carriers, the major advantages of hybrid CWDM/DWDM are:
• Reduced cost: CWDM has a significant cost advantage over DWDM due to the lower cost of lasers and the filters used in CWDM modules. Coarse channel spacing allows more tolerance for channel deviations or wavelength deviations. Therefore, CWDM transmitters and filters are easier, and cheaper, to manufacture. This cost saving becomes quite significant for large deployments.
• Pay-as-you-grow: Adding new channels one at a time allows for on-demand service introduction with minimal initial investment, a critical feature in times of reduced OPEX and CAPEX spending
• Investment protection: Although 8 channels may be enough in an initial deployment, it’s important to have an upgrade path to avoid a forklift upgrade to DWDM when growth in demand finally requires significant new capacity. Given the unique WaveReady upgrade capability, carriers no longer have to choose between CWDM and DWDM—both options can be deployed simultaneously or as part of a planned future, or incremental, upgrade. WaveReady 3000 series CWDM/DWDM modules can be used in either the WaveReady 3500, usually in central offices, or in the WaveReady 3100, usually on customer premises. Current capital investment can always be used in the upgraded network.
Hybrid DWDM/CWDM Optical Networks | 2
Theory of CWDM/DWDM Hybridization The CWDM frequency grid consists of 16 channels spaced at 20 nm intervals. The eight most commonly used channels are: 1470 nm, 1490 nm, 1510 nm, 1530 nm, 1550 nm 1570 nm, 1590 nm and 1610 nm. Within the pass band of these channels there exists the capacity to add 25 100 GHz spaced channels under the 1530 nm envelope and 25 more under the 1550 nm envelope if the filter is properly designed. For example, in the 1530 nm window there is a total theoretical pass band of ±10 nm on either side of the nominal center frequency. Therefore, one can, theoretically, concatenate multiple WDM filters to add another 25 channels within the pass-band. Looking at the ITU grid in Table 1 one can easily pick out these channels. Table 1: Theoretical Availability of Channels in the 1530 nm and 1550 nm Pass-band
1521.02 1540.56 1521.79 1541.35 1522.56 1542.14 1523.34 1542.94 1524.11 1543.73 1524.89 1544.53 1525.66 1545.32 1526.44 1546.12 1527.22 1546.92 1527.99 1547.72 1528.77 1548.51 1529.55 1549.32 1530.33 1550.12 1531.12 1550.92 1531.90 1551.72 1532.68 1552.52 1533.47 1553.33 1534.25 1554.13 1535.04 1554.94 1535.82 1555.75 1536.61 1556.55 1537.40 1557.36 1538.19 1558.17 1538.98 1558.98
1530 nm ± 20 nm
1539.77
1550 nm ± 20 nm
1559.79
Hybrid DWDM/CWDM Optical Networks | 3
Practical Application of CWDM/DWDM Hybridization In practice, adding another 25 channels in the pass-band of both the 1530 nm and 1550 nm CWDM channels is not achievable because the optical filters are not perfect square functions. The actual filter profile affects the number of channels which can be accommodated. However, actual JDS Uniphase DWDM filter technology does allow 38 additional channels to clear the CWDM archway as shown in Table 2. Table 2: Actual Availability of Channels in the 1530 nm and 1550 nm Pass-band
1521.02 1540.56 1521.79 1541.35 1522.56 1542.14 1523.34 1542.94 1524.11 1543.73 1524.89 1544.53 1525.66 1545.32 1526.44 1546.12 1527.22 1546.92 1527.99 1547.72 1528.77 1548.51 1529.55 1549.32 1530.33 1550.12 1531.12 1550.92 1531.90 1551.72 1532.68 1552.52 1533.47 1553.33 1534.25 1554.13 1535.04 1554.94 1535.82 1555.75 1536.61 1556.55 1537.40 1557.36 1538.19 1558.17 1538.98 1558.98
1530 nm ±20 nm
1539.77
1550 nm ±20 nm
1559.79
Hybrid DWDM/CWDM Optical Networks | 4
The system impact to adding these channels is equivalent to adding the component in line with existing CWDM equipment. The insertion losses add linearly. Figure 1 shows the infrastructure in a fully populated CWDM system.
147014901510
15501570
1530
15901610
CW
DM
8 CW
DM
8
TX1
TX2
TX3
TX4
TX5
TX6
TX7
TX8
MUX DeMUX
RX1
RX2
RX3
RX4
RX5
RX6
RX7
RX8
To add more channels to MUX side of this network, one would plug in a DWDM MUX with the appropriate channels to fall under the pass-band of the existing CWDM filters. Figure 2 shows the infrastructure of Figure 1 upgraded with 38 additional 100 GHz spaced channels. Figure 2: Forty Four Channel Hybrid CWDM/DWDM System
147014901510
157015901610
CW
DM
8 CW
DM
8
TX1
TX2
TX3
TX6
TX7
TX8
MUX DeMUX
RX1
RX2
RX3
RX6
RX7
RX8
DWDM
DWDM
1530
1550
19DWDM
TXs
19DWDM
TXs
DWDM
DWDM
The number of channels present in Figure 2 is 38 DWDM channels plus the existing six CWDM channels for a total of 44. The equipment required to go from the first architecture to the second are 2 DWDM multiplexers and demultiplexers, as well as the additional transmitter and receiver pairs required. The additional loss incurred by the upgrade is equal to the additional loss of the DWDM elements and the additional connection points. Several network types could take advantage of the architecture shown in Figure 2. For example one could increase the capacity of an existing ring, by deploying all of the elements above at each node. Or, one could allow DWDM traffic to overlay an existing CWDM network at a pre-determined crossover point.
Hybrid DWDM/CWDM Optical Networks | 5
Figure 3: Hybrid CWDM/DWDM Rings
The two networks would be configured in such a way to allow the DWDM traffic to travel across the CWDM ring. All of the nodes where the DWDM traffic would travel on the CWDM ring would require the DWDM multiplexer and demultiplexer pairs. Another application for the DWDM channels is for long reach links in CWDM rings. If a certain span exists in a CWDM network with a large distance between regenerators, say 100 km, DWDM channels can be used in place of CWDM ones to overcome this distance.
RXRXRXRXRXRXRXRX
CWDM NODE147014901510
15501570
1530
15901610
DWDM NODERXRXRX
RXRXRX
147014901510
157015901610
MIXED NODE
CWDM RING
DWDM Metro Core RING
Hybrid DWDM/CWDM Optical Networks | 6
System Impact The added components on the CWDM ring will decrease the link budget for each span by the amount of insertion loss for each new component. The use of high isolation optical filters for the DWDM channels will ensure that cross talk is minimized between closely spaced channels. In the case of very high channel counts, non-linear effects should be taken into consideration. These include self phase modulation and four wave mixing. The lasers used in DWDM networks have a much narrower line width than lasers used in CWDM. As a result the DWDM signals will typically have farther reach, and will undergo less pulse broadening due to chromatic dispersion. However they also lie within the operating range of erbium doped fiber amplifiers. This means that DWDM signals can go un-regenerated for large distances. This limit is reached at the transmitter’s dispersion limit. Receiver technology is independent of the optical signal present. The same receiver can be used to resolve a CWDM signal as well as a DWDM signal. The InGaAs material used to convert the optical signal into an electrical one has an operating range that includes both wavelength schemes. In the case of a 3R receiver, the receiver should be chosen such that it is compatible with the transmitter’s data rate. Glossary DCF – Dispersion Compensating Fiber DWDM – Dense Wavelength Division Multiplexing EDFA – Erbium-Doped Fiber Amplifier IEEE – Institute of Electrical and Electronics Engineers, Inc. ITU-T – International Telecommunication Union – Telecommunication Standardization Section SONET – Synchronous Optical Networks Featured Products Description WaveReady 3000 Bi-directional 1310 nm to CWDM transponder (WSH 500) WaveReady 3000 Bi-directional 850 nm to CWDM transponder (WSH 510) WaveReady 3000 Bi-directional 1310 nm to DWDM transponder (WSH 413) WaveReady 3000 Bi-directional 850 nm to DWDM transponder (WSH 400) WaveReady 3000 Communications Module 100 WaveReady 3500 Shelf Mounting Solution (DenseMount Shelf) Additional Information For more information on WaveReady™ or other products and their availability, please contact your local JDS Uniphase account manager or JDS Uniphase directly at 1-800-498-JDSU (5378) in North America and +800-5378-JDSU worldwide or via e-mail at [email protected]. WaveReady and JDS Uniphase are registered trademarks of JDS Uniphase Corporation.
