jgimenoIWM-12/1/2004 Fiber Optic module 1 STUDIES AND DEVELOPMENT OF A FIRST FIBER OPTIC MODULE PROTOTYPE Javier Gimeno Vicente
IWM-12/1/2004 Fiber Optic module2 jgimeno CONTENTS Why a Fiber Optic module? Characteristics of the link Attenuation: link between two BICs Optical power budget analysis Optical components “Detection and switch” TESTS BIDI MODULE solution TRANSCEIVER MODULE solution ELED or “Agilent” solution DISCRETE BIDI solution Conclusions Future works
IWM-12/1/2004 Fiber Optic module3 jgimeno Why a Fiber Optic module? Beam Permit Loops We don’t transmit data 10MHz control signal Freq = OK No freq. = beam dump
IWM-12/1/2004 Fiber Optic module4 jgimeno Why a Fiber Optic module? Responsible of receiving the Beam Permit signal (10MHz if OK), interrupting if a client activates a beam dump request, and transmitting the resulting signal. CONSTRAINTS: fast, simple and RELIABLE. Fast requirements: to convert the light into voltage to interrupt (switch) the signal to convert the signal into light.
IWM-12/1/2004 Fiber Optic module5 jgimeno Characteristics of the link (1/2) BIC layout in the LHC
IWM-12/1/2004 Fiber Optic module6 jgimeno Characteristics of the link (2/2) Characteristics fixed and determined by: Fiber Distance between BICs Connectors All the links must fulfil the optical power budget rule Single mode suitable for 1310nm and 1550nm wavelengths Attenuation: 0.5dB/Km (worst case) Degradation during time negligible Typical delay of 5ns/m (worst case: half LHC (~13.5Km) ~67.5µs) max.: 3.3Km (BICs in different IPs) min.: some meters (BICs in the same room) Any possible Recommended and used at CERN: E2000/APC Losses: 0.5dB in each connector (worst case)
IWM-12/1/2004 Fiber Optic module7 jgimeno Attenuation: link between two BICs Minimum attenuation: BICs in the same room Maximum attenuation: BICs in different IPs Safety margin min. 2dB typ. 3dB (Honeywell…)
IWM-12/1/2004 Fiber Optic module8 jgimeno Optical power budget analysis Optical power margin rule It determines the optical power characteristics of the transmitter and receiver
IWM-12/1/2004 Fiber Optic module9 jgimeno Optical components (1/3) Types Electrical characteristics DISCRETE: - Analog interface - Development of the analog to digital conversion MODULE: - Optical component + digital interface Optical characteristics OPTICAL TRANSMITTER: - LED: Surface-emitting LED, Edge-emitting LED (ELED), Superluminescent LED (SLED)… - LASER: Laser Diode (LD), Vertical Cavity Surface-emitting Laser (VCSEL)… OPTICAL RECEIVER: - PIN (positive-intrinsic-negative) photodiode - Avalanche photodiode (APD)
IWM-12/1/2004 Fiber Optic module10 jgimeno Optical components (2/3) *WDM: Wave Division Multiplex BIDIrectional TRANSCEIVER DETAIL TRANSCEIVER or TRANSMITTER AND RECEIVER: - Independent transmitter and receiver - 2 fibers to transmit and receive (same wavelengths) BI-DI TRANSCEIVER: - Transmitter and receiver in the same device - ONLY 1 fiber to transmit and receive (different wavelengths) 2 topologies using
IWM-12/1/2004 Fiber Optic module11 jgimeno Optical components (3/3) SOLUTIONCHARACTERISTICSCOMPANY BIDI MODULE SOLUTION 1 fiber to transmit and receiver BIDI module (standard package) ITEC Infineon TRANSCEIVER MODULE SOLUTION 2 fibers to transmit and receiver Module component (standard package) ITEC ELED or “Agilent” SOLUTION 2 fibers to transmit and receiver Discrete components Agilent design Agilent and PD-LD DISCRETE BIDI SOLUTION 1 fiber to transmit and receiver Discrete components Development of analog to digital interface Afonics OTHER SOLUTIONS S.I.Tech ONTi Eva Calvo Cypress Selection
IWM-12/1/2004 Fiber Optic module12 jgimeno DETECTION and SWITCH (1/2) Not complex (but must be RELIABLE!!): SWITCH: simple AND gate Frequency Detection “By edge”, using counters “By sample”, using a shift register to sample
IWM-12/1/2004 Fiber Optic module13 jgimeno DETECTION and SWITCH (2/2) Proposed circuit for the TESTS REGENERATION NO REGENERATIONREGENERATION + 1 source of 10MHz in the first BIC: if no RX signal (10 MHz) no TX signal + TX signal depends on BEAM PERMIT SIGNAL and ENABLE signal ± Redundancy: FREQUENCY DETECT, but adds an extra-delay - Integrity of the 10 MHz signal has to be tested + Regeneration of the 10 MHz signal - 1 source in each BIC: no RX signal (10 MHz) ≠ no TX signal - TX signal depends only on TX ENABLE signal - Less reliable
IWM-12/1/2004 Fiber Optic module14 jgimeno BIDI MODULE Solution (1/3) DESIGN: Very simple Digital conversion Prototype board
IWM-12/1/2004 Fiber Optic module15 jgimeno BIDI MODULE Solution (2/3) TESTS Without “detection and switch” Without attenuator, only fiber optic cable of 10m
IWM-12/1/2004 Fiber Optic module16 jgimeno BIDI MODULE Solution (3/3) RESULTS: + BIDI MODULES (ITEC and Infineon) fulfil the optical power budget rule (minimum transmitter output power -15dBm / Receiver sensibility: -33dBm) - RECEIVERS PROBLEM: AGC in TIAs don’t allow the transmission of signal below ~100kHz Not good “switch” from 10MHz to DC signal - Same results for TRANSCEIVER MODULE SOLUTION CONCLUSION : SOLUTION(S) NOT GOOD TX RX SD TX RX SD
IWM-12/1/2004 Fiber Optic module17 jgimeno ELED or “Agilent” Solution (1/3) DESIGN: Agilent design Simple but ELEDs quite expensive ELEDs board standard package (it can be used with BIDI prototype board after some modifications) Modified BIDI prototype board
IWM-12/1/2004 Fiber Optic module18 jgimeno ELED or “Agilent” Solution (2/3) FIRST TEST: transmission, attenuation and detection RESULTS: + PD-LD ELED with Agilent receiver fulfill the optical power budget rule (minimum transmitter output power -23dBm / Receiver sensibility: -33dBm) + Max. attenuation: 12dB + REGENERATION is not necessary + Lost of frequency correctly detected TX RX DETECT TX RX
IWM-12/1/2004 Fiber Optic module19 jgimeno ELED or “Agilent” Solution (3/3) SECOND TEST: beam permit loop simulation CONCLUSION : SOLUTION WORKING TX (BIC 1) ALARM (BIC 2) ReTX (BIC 2) DETECT (BIC 3) TX (BIC 1) ALARM (BIC 2) ReTX (BIC 2) DETECT (BIC 3)
IWM-12/1/2004 Fiber Optic module20 jgimeno DISCRETE BIDI Solution (1/2) DESIGN: - Complex design (laser, very low analog signals, board design…) + Allow flexibility (selection of components, optical power…) COMPONENTS: Discrete BIDI: Afonics (although lots similar) TX circuit: MAX3263 (laser driver, Maxim) RX circuit: SA5212 (TIA, Philips) + postamplifier (LT1016, Agilent board)
IWM-12/1/2004 Fiber Optic module21 jgimeno DISCRETE BIDI Solution (2/2) RESULTS: + Design fulfill the optical power budget rule Transmitter output power: -27.5dB for “0” / -2.5dB for “1” Adjustable Receiver sensibility: ~-30dB (R=0.5 A/ W it depends also on electronics) - Must avoid receiver saturation - Integrity of the signal (fall/rise time) + More power more margin of attenuation + Max. attenuation: 27.5dB (up to 50Km of fiber!!!!) CONCLUSIONS: SOLUTION WORKING New board and more tests necessary BUT STILL IN PROGRESS
IWM-12/1/2004 Fiber Optic module22 jgimeno OTHER SOLUTIONS S.I. Tech solution: Similar to Agilent solution (discrete components + analog to digital conversion) Don’t allow transmission of DC signals ONTi: Chinese company with interests in working with CERN Development for us Good products and good price… but must be tested Eva Calvo Design: DC transmission, reliability… and radioactivity Powerful transmitters (~1mW) Discrete components + special electronic circuit: analog circuit + ECL Tested and working Cypress Transmitter circuit = Agilent design RX circuit with PECL postamplifier increases bandwidth
IWM-12/1/2004 Fiber Optic module23 jgimeno CONCLUSIONS MODULE solutions simple but not working well 2 solutions working: ELED or Agilent solution simple DISCRETE BIDI solution it uses only 1 fiber and allows more margin of attenuation, but complex and more tests necessary “Detection and switch” working No regeneration necessary detection only in the last module (should be tested)
IWM-12/1/2004 Fiber Optic module24 jgimeno FUTURE WORKS Preparation of LHC simulation (using Agilent solution) with several modules in a loop New board and more tests using DISCRETE BIDI solution “Detection and switch” how and where (Core or Fiber Optic module)? Conclusions: more tests, new boards, more components (attenuators)… more money and more time!! Still a lot of work before taking the FINAL DECISSION
IWM-12/1/2004 Fiber Optic module25 jgimeno QUESTIONS?