Dataset for the article: Experimental characterization of an O-band bismuth-doped fiber amplifier
Dataset for the article: Experimental characterization of an O-band bismuth-doped fiber amplifier
This dataset contains:
Sheet 1:
Fig. 2. (b) an example of electrical power spectra measured by the RFSA that were used to determine the electrical NF of the BDFA at the wavelength of 1350nm and the input power (Pin) = -20dBm.
col(A) = Frequnecy (HZ)
col(B) = RFSA_cal (dBm)
col(C) = RFSA_meas (dBm)
col(D) = RFSA_ther (dBm)
Sheet 2:
Fig. 3. (a) frequency dependent NF of the BDFA (Pin=-20dBm).
col(A) = Frequency (Hz)
col(B) = NF_1310nm (dB)
col(C) = NF_1330nm (dB)
col(D) = NF_1350nm (dB)
col(E) = NF_1360nm (dB)
Sheet 3:
Fig. 3. (b) averaged NF of the BDFA as it varies with wavelength (Pin=-20dBm).
(Note - this is a double y-axis plot)
col(A) = x1:Wavelength (nm)
col(B) = y1:NF (dB)
col(C) = x2:Wavelength (nm)
col(D) = y2:Gain (dB)
Sheet 4:
Fig. 3. (c) frequency dependent NF of the SOA (Pin=-20dBm).
col(A) = Frequency (Hz)
col(B) = NF_1310nm (dB)
col(C) = NF_1330nm (dB)
col(D) = NF_1350nm (dB)
col(E) = NF_1360nm (dB)
Sheet 5:
Fig. 3. (d) averaged NF of the SOA as it varies with wavelength (Pin=-20dBm).
(Note - this is a double y-axis plot)
col(A) = x1:Wavelength (nm)
col(B) = y1:NF (dB)
col(C) = x2:Wavelength (nm)
col(D) = y2:Gain (dB)
Sheet 6:
Fig. 4. Averaged NF of the BDFA at the wavelength of 1350nm as it varies with input power.
col(A) = Pin (dBm)
col(B) = Avg NF BDFA at 1350nm (dB)
Sheet 7:
Fig. 5. (b) gain tilt results.
col(A) = Wavelength (nm)
col(B) = -5dBm-Static (dB/nm)
col(C) = 0dBm-Static (dB/nm)
col(D) = 5dBm-Static (dB/nm)
col(E) = 10dBm-Static (dB/nm)
col(F) = -5dBm-Dynamic (dB/nm)
col(G) = 0dBm-Dynamic (dB/nm)
col(H) = 5dBm-Dynamic (dB/nm)
col(I) = 10dBm-Dynamic (dB/nm)
Sheet 8:
Fig. 6. (b) power excursion of the small probe signal as a function of the modulation frequency.
(Note - this is a double y-axis plot)
col(A) = x1:BDFA - Mod Freq (kHz)
col(B) = y1:BDFA - Power excursion (dB)
col(C) = x2:SOA - Mod Freq (kHz)
col(D) = y2:SOA - Power excursion (dB)
Sheet 9:
Fig. 6. (b) inset shows the optical signals modulated at 50kHz, as observed on the OSC.
(Note - this is a double y-axis plot)
col(A) = x1:Amplified saturating signal - Time (sec)
col(B) = y1:Amplified saturating signal - Normalised amplitude
col(C) = x2:Probe with x10 magnification and vertical offet - Time (sec)
col(D) = y2:Probe with x10 magnification and vertical offet - Amplitude
Sheet 10:
Fig. 7. (b)PDG results of the BDFA at 1350nm with varied input power.
col(A) = Input power (dBm)
col(B) = PDG (dB)
Sheet 11:
Fig. 7. (c) PDG results of the BDFA at 1350nm wavelength dependent PDG at -10-dBm input power.
col(A) = Wavelength (nm)
col(B) = PDG (dB)
University of Southampton
Taengnoi, Natsupa
1c9a8f38-f378-426c-9b5a-75e0bc165afd
Bottrill, Kyle
8c2e6c2d-9f14-424e-b779-43c23e2f49ac
Hong, Yang
73d5144c-02db-4977-b517-0d2f5a052807
Wang, Yu
629093a5-d7b6-408d-86bf-d2e754f739e6
Thipparapu, Naresh Kumar
a36a2b4c-b75c-4976-a753-b5fab9e54150
Sahu, Jayanta
009f5fb3-6555-411a-9a0c-9a1b5a29ceb2
Petropoulos, Periklis
522b02cc-9f3f-468e-bca5-e9f58cc9cad7
Richardson, David
ebfe1ff9-d0c2-4e52-b7ae-c1b13bccdef3
Taengnoi, Natsupa
1c9a8f38-f378-426c-9b5a-75e0bc165afd
Bottrill, Kyle
8c2e6c2d-9f14-424e-b779-43c23e2f49ac
Hong, Yang
73d5144c-02db-4977-b517-0d2f5a052807
Wang, Yu
629093a5-d7b6-408d-86bf-d2e754f739e6
Thipparapu, Naresh Kumar
a36a2b4c-b75c-4976-a753-b5fab9e54150
Sahu, Jayanta
009f5fb3-6555-411a-9a0c-9a1b5a29ceb2
Petropoulos, Periklis
522b02cc-9f3f-468e-bca5-e9f58cc9cad7
Richardson, David
ebfe1ff9-d0c2-4e52-b7ae-c1b13bccdef3
Taengnoi, Natsupa, Bottrill, Kyle, Hong, Yang, Wang, Yu, Thipparapu, Naresh Kumar, Sahu, Jayanta, Petropoulos, Periklis and Richardson, David
(2024)
Dataset for the article: Experimental characterization of an O-band bismuth-doped fiber amplifier.
University of Southampton
doi:10.5258/SOTON/D1780
[Dataset]
Abstract
This dataset contains:
Sheet 1:
Fig. 2. (b) an example of electrical power spectra measured by the RFSA that were used to determine the electrical NF of the BDFA at the wavelength of 1350nm and the input power (Pin) = -20dBm.
col(A) = Frequnecy (HZ)
col(B) = RFSA_cal (dBm)
col(C) = RFSA_meas (dBm)
col(D) = RFSA_ther (dBm)
Sheet 2:
Fig. 3. (a) frequency dependent NF of the BDFA (Pin=-20dBm).
col(A) = Frequency (Hz)
col(B) = NF_1310nm (dB)
col(C) = NF_1330nm (dB)
col(D) = NF_1350nm (dB)
col(E) = NF_1360nm (dB)
Sheet 3:
Fig. 3. (b) averaged NF of the BDFA as it varies with wavelength (Pin=-20dBm).
(Note - this is a double y-axis plot)
col(A) = x1:Wavelength (nm)
col(B) = y1:NF (dB)
col(C) = x2:Wavelength (nm)
col(D) = y2:Gain (dB)
Sheet 4:
Fig. 3. (c) frequency dependent NF of the SOA (Pin=-20dBm).
col(A) = Frequency (Hz)
col(B) = NF_1310nm (dB)
col(C) = NF_1330nm (dB)
col(D) = NF_1350nm (dB)
col(E) = NF_1360nm (dB)
Sheet 5:
Fig. 3. (d) averaged NF of the SOA as it varies with wavelength (Pin=-20dBm).
(Note - this is a double y-axis plot)
col(A) = x1:Wavelength (nm)
col(B) = y1:NF (dB)
col(C) = x2:Wavelength (nm)
col(D) = y2:Gain (dB)
Sheet 6:
Fig. 4. Averaged NF of the BDFA at the wavelength of 1350nm as it varies with input power.
col(A) = Pin (dBm)
col(B) = Avg NF BDFA at 1350nm (dB)
Sheet 7:
Fig. 5. (b) gain tilt results.
col(A) = Wavelength (nm)
col(B) = -5dBm-Static (dB/nm)
col(C) = 0dBm-Static (dB/nm)
col(D) = 5dBm-Static (dB/nm)
col(E) = 10dBm-Static (dB/nm)
col(F) = -5dBm-Dynamic (dB/nm)
col(G) = 0dBm-Dynamic (dB/nm)
col(H) = 5dBm-Dynamic (dB/nm)
col(I) = 10dBm-Dynamic (dB/nm)
Sheet 8:
Fig. 6. (b) power excursion of the small probe signal as a function of the modulation frequency.
(Note - this is a double y-axis plot)
col(A) = x1:BDFA - Mod Freq (kHz)
col(B) = y1:BDFA - Power excursion (dB)
col(C) = x2:SOA - Mod Freq (kHz)
col(D) = y2:SOA - Power excursion (dB)
Sheet 9:
Fig. 6. (b) inset shows the optical signals modulated at 50kHz, as observed on the OSC.
(Note - this is a double y-axis plot)
col(A) = x1:Amplified saturating signal - Time (sec)
col(B) = y1:Amplified saturating signal - Normalised amplitude
col(C) = x2:Probe with x10 magnification and vertical offet - Time (sec)
col(D) = y2:Probe with x10 magnification and vertical offet - Amplitude
Sheet 10:
Fig. 7. (b)PDG results of the BDFA at 1350nm with varied input power.
col(A) = Input power (dBm)
col(B) = PDG (dB)
Sheet 11:
Fig. 7. (c) PDG results of the BDFA at 1350nm wavelength dependent PDG at -10-dBm input power.
col(A) = Wavelength (nm)
col(B) = PDG (dB)
Spreadsheet
Dataset_for_PURE_BDFA_characterisation_Optics_Express.xlsx
- Dataset
Text
Readme.txt
- Dataset
More information
Published date: 2024
Identifiers
Local EPrints ID: 486869
URI: http://eprints.soton.ac.uk/id/eprint/486869
PURE UUID: cf8d6761-de9d-490d-9669-3968e63e3221
Catalogue record
Date deposited: 07 Feb 2024 17:47
Last modified: 08 Feb 2024 02:46
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