METHOD OF DETERMINING AN OPTIMUM PATH IN AN OPTICAL TELECOMMUNICATIONS NETWORK

Abstract

This invention concerns the field of telecommunication networks using optical fibres. The invention relates to a method of determining a connection path between two points in an optical network comprising several paths to connect said two points, each path comprising optical fibre spans and power amplifiers, said method comprising different steps depending on the degree of knowledge of network optical data. This data consists of the optical losses LI in optical fibre spans, the maximum allowable input power IP into said spans and the maximum output power PA from the amplifiers.

Description

The invention will be better understood and other advantages will become clearer after reading the following description given non-limitatively with reference to the appended figures, wherein:

FIG. 1 represents a part of an optical network comprising nodes and spans;

FIG. 2 shows a span between two nodes with an indication of the different elements making up this span;

FIG. 3 shows the flowchart for the method according to the invention.

As already mentioned, the important parameter characterising the path between two nodes is the signal to noise ratio or OSNR. For a span S_I, the OSNR_I is given by the optical amplifier A_I of the span. The signal/noise ratio is conventionally calculated for a spectral band B_f with a width of 0.1 nanometres. This spectral width is equal to the wavelength of 1550 nanometers, at a frequency width of 12.5 GHz.

The OSNR_I is calculated in dB. Its expression is equal to:

OSNR _I(dB/nm)=P_AII(dBm)−NF_AI(dB)+K  Equation 1

• • where P_AII: Input power of the optical amplifier A_I
  • NF_AI: Noise figure of the optical amplifier A_I
  • K: constant equal to −10.Log(h.v.B_f) where h=Planck's constant and v=optical frequency of the signal.

For optical telecommunications applications operating at a wavelength of 1550 nanometers, K is equal to about 58.

With optical losses for the optical link equal to L_I, the input power P_AII of the optical amplifier A_I is equal to:

P _AII(dBm)=P_II(dBm)−L_I(dB)  Equation 2

• • where P_II: Input power in span L_I

Consequently, the OSNR_I is also given by substituting the expression for the input power P_AII given by equation 2, in equation 1:

OSNR _I(dB/nm)=P_II(dBm)−L_I(dB)−NF_AI(dB)+K  Equation 3

In the following equations, to simplify the presentation, the different units will no longer be indicated, since the powers are all expressed in dBm and the attenuations in dB.

The signal to noise ratio OSNR for a path comprising N spans S_I each with a signal to noise ratio OSNR_I is equal to:

$1/\mathrm{OSNR}=\sum _{i=1}^N1/{\mathrm{OSNR}}_I$

which can also be written in the following form:

$\begin{array}{cc}\mathrm{OSNR}=10·{\mathrm{Log}}_{10}\left(\sum _{i=1}^N{10}^{\left(P_{\mathrm{II}}-L_i-{\mathrm{NF}}_{\mathrm{AI}}+K\right)/10}\right)& \mathrm{Equation}4\end{array}$

Using this expression, and depending on knowledge of the optical telecommunications network, several assumptions can be made to simplify the calculation of the OSNR for an optical path.

Assumption A: Only optical losses L_I in optical fibre spans are known.

In this case, it can be considered that:

• • the input powers P_II in each span S_I are identical and equal to P_I;
  • the noise figures NF_AI of optical amplifiers A_I are identical and equal to NF_A.

Equation 4 can then be written:

$\begin{array}{cc}\mathrm{OSNR}=P_I-{\mathrm{NF}}_A+K-10·{\mathrm{Log}}_{10}\left(\sum _{i=1}^N{10}^{L_I/10}\right)& \mathrm{Equation}5\end{array}$

that can be put in the form:

OSNR=K _A −IL

• where K_A is a constant independent of the path chosen
• and

$\mathrm{IL}=10·{\mathrm{Log}}_{10}\left(\sum _{i=1}^N{10}^{\mathrm{Li}/10}\right).$

•  is dependent on the path chosen and is equal to the integration losses of the path.

Consequently, in assumption A, the signal to noise ratio can be optimised by choosing the path with the lowest integration losses IL, said losses being calculated using the expression in equation 5.

Assumption B: The optical losses L_I in optical fibre spans are known, together with the maximum allowable input power IP in said spans.

In this case, we can write:

P _I =IP−10 Log N  Equation 6

Substituting the expression for P_I given in equation 6 into equation 5, we obtain:

$\begin{array}{cc}\mathrm{OSNR}=\mathrm{IP}-10·\mathrm{Log}N-{\mathrm{NF}}_A+K-10·{\mathrm{Log}}_{10}\left(\sum _{i=1}^N{10}^{L_I/10}\right)& \mathrm{Equation}7\end{array}$

Consequently, in assumption B, the path with the highest OSNR should be chosen, said OSNR being calculated using the expression in equation 7.

Assumption C: Optical losses L_I in optical fibre spans are known, the maximum allowable input power IP in said spans and the maximum output power P_A from the amplifiers are also known.

In this case, the input power into the optical fibres may be limited:

• • Either, as in the case of assumption B, by the maximum allowable input power IP;
  • Or by the maximum output power P_A from the amplifiers.

In the first case, the input power into the optical fibres is equal to:

P _I =IP−10 Log N  Equation 6

In the second case, the input power into the optical fibres is equal to:

P _I =P _A−10 Log C  Equation 8

with C: Number of multiplexed channels circulating in the optical fibre. In fact, in optical fibre spans, the signals are usually multiplexed either in time or spectrally so as to increase the throughput of the span. Therefore the power output by an amplifier is distributed on the C channels transmitted by the optical fibre.

Therefore for each path, we need to determine:

• • Firstly, the input power corresponding to the minimum of the expressions given by equations 6 and 8;
  • Secondly, this minimum being known, the corresponding signal to noise ratio using equation 5.

The three assumptions for the method according to the invention are summarized in the flowchart in FIG. 3. Obviously, the installation of this method in a calculator or in a computer for the purpose of automatically determining the best possible path will not introduce any particular technical problems.

This method has the advantage of making the best use of technical information about a telecommunications network and optimising the choice of a path as a function of knowledge of this information.

Claims

1. Method of determining a connection path between two points in an optical network comprising several paths to connect said two points, each path comprising optical fibre spans and power amplifiers, said method being such that: a) If only the optical losses LI in the optical fibre spans are known, then the method comprises the following 3 steps: Calculation of integration losses for at least a first and a second path between said two points;Comparison between said losses;Choice of the path that minimizes said losses;b) If only the optical losses LI in the optical fibre spans and the maximum allowable input power IP into said spans are known, then the method comprises the following 3 steps: Calculation of the Optical Signal to Noise Ratio (OSNR) for at least a first and a second path between said two points assuming that the power injected into each span is equal to the maximum allowable input power;Comparison between said signal/noise ratios;Choice of the path that maximizes said signal/noise ratios;c) If the optical losses LI in the optical fibre spans are known, the maximum allowable input power IP into said spans and the maximum output power PA of the amplifiers are known, then the method comprises the following four steps: Calculation of the real allowable power in the spans;Calculation of the signal to noise ratio for at least a first and a second path between said two points assuming that the power injected into each span corresponds to the maximum real allowable power;Comparison between said signal/noise ratios;Choice of the path maximizing said signal/noise ratios.

2. Method of determining a connection path according to case a) in claim 1, characterised in that a path is comprising N optical fibre spans, each span having an optical loss PI expressed in dB, the integration losses IL in dB for said path are calculated using the following expression:

3. Method of determining a connection path according to case b) in claim 1, characterised in that: a path comprising N optical fibre spans, each span having an optical loss LI expressed in dB, the integration losses IL in dB for said path are calculated using the expression:

4. Method of determining a connection path according to claim 3, characterised in that the constant K is equal to approximately 58.

5. Method of determining a connection path according to case c) in claim 1, characterised in that: a path comprising N optical fibre spans, each span having an optical loss LI expressed in dB, the integration losses IL in dB for said path are calculated using the expression:

6. Method of determining a connection path according to claim 5, characterised in that the constant K is equal to approximately 58.