# Calculating Power Budget and Power Margin for Fiber-Optic Cables

Use the information in this topic and the specifications for your optical interface to calculate the power budget and power margin for fiber-optic cables.

You can use the Hardware Compatibility Tool to find information about the pluggable transceivers supported on your Juniper Networks device.

To calculate the power budget and power margin, perform the following tasks:

## Calculate Power Budget for Fiber-Optic Cables

To ensure
that fiber-optic connections have sufficient power for correct operation, you
need to calculate the link's power budget (P_{B}), which is the maximum
amount of power it can transmit. When you calculate the power budget, you use a
worst-case analysis to provide a margin of error, even though all the parts of
an actual system do not operate at the worst-case levels. To calculate the
worst-case estimate of P_{B}, you assume minimum transmitter power
(P_{T}) and minimum receiver sensitivity (P_{R}):

P_{B} = P_{T} –
P_{R}

The following hypothetical power budget equation uses values measured in decibels (dB) and decibels referred to one milliwatt (dBm):

P_{B} = P_{T }–
P_{R}

P_{B} = –15 dBm – (–28
dBm)

P_{B} = 13 dB

## How to Calculate Power Margin for Fiber-Optic Cables

After calculating a link's P_{B}, you can calculate the power margin (P_{M}),
which represents the amount of power available after subtracting attenuation or
link loss (LL) from the P_{B}) A worst-case estimate of P_{M}
assumes maximum LL:

P_{M} = P_{B} –
LL

P_{M} greater than zero indicates that the power budget is sufficient to operate the
receiver.

Factors that can cause link loss include higher-order mode losses, modal and chromatic dispersion, connectors, splices, and fiber attenuation. Table 1 lists an estimated amount of loss for the factors used in the following sample calculations. For information about the actual amount of signal loss caused by equipment and other factors, refer to vendor documentation.

Link-Loss Factor |
Estimated Link-Loss Value |
---|---|

Higher-order mode losses |
Single mode—None Multimode—0.5 dB |

Modal and chromatic dispersion |
Single mode—None Multimode—None, if product of bandwidth and distance is less than 500 MHz-km |

Faulty connector |
0.5 dB |

Splice |
0.5 dB |

Fiber attenuation |
Single mode—0.5 dB/km Multimode—1 dB/km |

The following sample calculation for a 2-km-long multimode link with a P_{B} of 13 dB
uses the estimated values from Table 1.
This example calculates LL as the sum of fiber attenuation (2 km @ 1 dB/km, or
2 dB) and loss for five connectors (0.5 dB per connector, or 2.5 dB) and two
splices (0.5 dB per splice, or 1 dB) as well as higher-order mode losses
(0.5 dB). The P_{M} is calculated as follows:

P_{M} = P_{B} –
LL

P_{M} = 13 dB – 2 km (1 dB/km) –
5 (0.5 dB) – 2 (0.5 dB) – 0.5 dB

P_{M} = 13 dB – 2 dB – 2.5 dB
– 1 dB – 0.5 dB

P_{M} = 7 dB

The following sample calculation for an 8-km-long single-mode link with a P_{B} of 13 dB
uses the estimated values from Table 1.
This example calculates LL as the sum of fiber attenuation (8 km @ 0.5 dB/km, or
4 dB) and loss for seven connectors (0.5 dB per connector, or 3.5 dB). The
pP_{M} is calculated as follows:

P_{M} = P_{B} –
LL

P_{M} = 13 dB – 8 km (0.5 dB/km) –
7(0.5 dB)

P_{M} = 13 dB – 4 dB – 3.5 dB

P_{M} = 5.5 dB

In both the examples, the calculated P_{M} is greater than zero, indicating that the link
has sufficient power for transmission and does not exceed the maximum receiver
input power.