Device, remote node and methods for PON supervision

The invention claimed is: 1. A wavelength shifter module in a passive optical network (PON) configured to adapt an optical time domain reflectometry (OTDR) signal from an OTDR device for supervision of a drop section in the PON, the wavelength shifter module arranged in a fiber path between the OTDR device and a remote node (RN) and comprising: a first wavelength filter arranged to allow passage of light within a predetermined wavelength interval; a Raman wavelength shifter arranged to tune wavelengths of the filtered light to a range of wavelengths, wherein the range of wavelengths is selected based on information from one or more drop sections in the PON; a tunable filter tuned to allow passage of a pre-selected wavelength from the range of wavelengths from the Raman wavelength shifters, for monitoring of a specific drop section; and a pulse generation arrangement to erase an envelope of a main carrier of the pre-selected wavelength and remodulate light according to OTDR pulses; and a circulator to distribute the tuned light to a port in an optical distribution network (ODN) for monitoring the specific drop section. 2. The wavelength shifter module according to claim 1 , wherein the Raman wavelength shifter is included in a dedicated fiber feeder for the OTDR signal to the remote node in the PON. 3. The wavelength shifter module according to claim 1 , wherein the Raman wavelength shifter is arranged in the fiber path of a common feeder fiber for the OTDR signal and an information carrying light signal to the remote node in the PON. 4. The wavelength shifter module according to claim 1 , wherein the first wavelength filter is a red/blue filter (R/B filter). 5. The wavelength shifter module according to claim 4 , wherein an isolator is arranged downlink from the R/B filter to prevent leakage from backscattered light in the Raman wavelength shifter. 6. A method in a wavelength shifter module for supervision of an optical distribution network (ODN) in a passive optical network (PON), the method comprising: receiving an optical time domain reflectometry (OTDR) signal comprising at least one wavelength; filtering the received OTDR signal through a wavelength filter; shifting the at least one wavelength of the filtered OTDR signal by Stokes shifting to a range of wavelengths, wherein the range of wavelengths is selected based on information from one or more drop sections in the PON; filtering the wavelength shifted signal to allow passage of a wavelength shifted signal of a pre-selected wavelength through a tunable filter, wherein an envelope of a main carrier of the wavelength shifted signal of the pre-selected wavelength is erased and the filtered light is remodulated in conformity with OTDR pulse signaling; and outputting the wavelength shifted signal on a feeder fiber to the ODN for monitoring a specific drop section. 7. The method according to claim 6 , wherein the filtering of the received OTDR signal is a red/blue filtering. 8. A system for determining a location of at least one fault section in a drop section in a passive optical network (PON), comprising: an optical time domain reflectometry (OTDR) equipment in a central office node of the system; at least one remote node comprising a data splitter arrangement; and a wavelength shifter module at an output of the OTDR equipment, wherein the wavelength shifter module comprises: a first wavelength filter arranged to allow passage of light within a predetermined wavelength interval; a Raman wavelength shifter arranged to tune wavelengths of the filtered light to a range of wavelengths, wherein the range of wavelengths is selected based on information from one or more drop sections in the PON; a tunable filter tuned to allow passage of the filtered light of a pre-selected wavelength from the selected range of wavelengths from the Raman wavelength shifter, for monitoring of a specific drop section; and a pulse generation arrangement to erase an envelope of a main carrier of the pre-selected wavelength and remodulate light according to OTDR pulses; and a circulator to distribute the tuned light to the at least one remote node in the PON for monitoring the specific drop section.