TTC laser transmitter (TTCex, TTCtx, TTCmx) User Manual
Contents
1. 5 4 ns after the rising edge of the clock as shown in Fig 10 At 5 4 ns am 25ns CLOCK OUTPUT DATA INPUTS Fig 10 BC Delay timing adjustment The BC Delay switch allows the timing to be adjusted in steps of 2 ns and the switch position which gives the timing nearest the optimum setting should be chosen External trigger source timing In order to minimise the Level 1 trigger latency the TTCvi does not resynchronize the L1A lt 0 gt input which it receives from the Central Trigger Processor or other external trigger source Hence the timing of the TTCex A data input signal routed through the TTCvi from its LLA lt 0 gt input is not affected by the TTCvi BC Delay switch and it must be adjusted at the external trigger source itself to obtain the correct phasing at the A data input socket of the TTCex CLOCK OUTPUT A DATAINPUT KXAXXX KXAAAAXAXAAMA XXXXXAMA Fig 11 TTCex A channel timing for external trigger To set the timing for an external trigger source connected to the TTCvi LIA lt 0 gt input insert Lemo Y adapters at the CLK1 or CLK2 output and the appropriate A data input socket of the TTCex to allow these signals to be monitored with a scope probe Select LIA lt 0 gt trigger input in TTCvi CSR1 The duration and phasing of the external trigger signal source should be such that the TTCex A data input signal is valid for a minimum setup time of As 5 1 ns before the falling edge of the clock and a mi2. available throughout the lifetime of the LHC support will in due course be provided by EP Division ESS Group
3. experiment Finally if the TTCmi is powered off the TTCex modules continue to generate a 40 08 MHz clock from their internal quartz oscillators If desired for test purposes the TTCex modules can be driven by any other external clock source of frequency 40 079 MHz 50 ppm applied to the CLK input socket Note that 50 ppm is only 2 kHz so you cannot use a 40 00 MHz source An ECL swing signal is required and the internal termination is 50 Q to ground AC coupled Lemo cables During the mid 1990s CERN stores received a consignment of yellow labelled black Lemo cables of all lengths which had defective crimping causing intermittent contacts and many of these were distributed before the defect was discovered After the manufacturing problem was rectified the black Lemo cables were fabricated with green labels instead of yellow ones Current production is yellow labelled cables with a brown sheath In case any yellow labelled black cables are suspect change them for green labelled black ones or yellow labelled brown ones Internal jumpers Fig 5 TTCex in Single mode Fig 6 TTCex in Dual mode Two internal jumpers ST1 and ST2 allow the TTCex and TTCtx modules to be configured for Single or Dual operation There are no jumpers in the TTCmx module which cannot be operated in independent halves Figures 5 and 6 indicate the jumper positions for each mode of operation for the TTCex module while Figures 7 and 8 indicate the jumper positi
4. multimode optical patchcords for interconnecting the RD12 TTC distribution modules have been standardised in CERN stores in a range of overall lengths as follows 04 67 00 005 9 L 0 5 m 04 67 00 015 7 L 1 5 m 04 67 00 050 4 L 5m 04 67 00 150 1 L 15 m 04 67 00 500 9 L 50 m CERN stores do not supply separate optical fibre connectors or accessories like adapters couplings splices and attenuators 3M Dorran Type FO 6112 couplings suitable for concatenating the patchcords are available from Bruce Taylor Laser inhibit The TTCex TTCtx and TTCmx transmitter modules are equipped with a front panel switch which allows all the optical outputs to be disabled The TTCex and TTCtx lasers can also be disabled by pulling low the VMEbus SYSFAIL line The signal input is compatible with the VMEbus standard but also has a pull up so that the modules can be used in a lower cost 6U crate with only power supplies and no terminated VME dataway In the case of the TTCm lt x the inhibit facility is available at pin z24 of the module connector TTL load with internal pull up 1K to 5v 10 A red LED on the front panel indicates when the lasers are active The hazard level is Class 1 but output connectors or fibre ends should not be viewed with optical instruments Laser characteristics The transmitter modules use multi sourced InGaAsP low threshold MOW hermetic package Fabry Perot lasers rated for operation at 0 to 55 C The operating wa
5. B G Taylor RD12 working document Rev 2 0 TTC laser transmitter TTCex TTCtx TTCmx User Manual Three types of laser transmitter module have been developed by RD12 for TTC signal distribution at the experiments The two main modules see Fig 1 are single width 6U VME size and use only standard VMEbus power supplies The modules can be used separately or in combination to match the requirements of a variety of different TTC distribution architectures WEF ETRE i ud t TEH aoa cies 5 j H IPF E gt s amp iy amp 2 S a Fig 1 TTCex and TTCtx laser transmitter modules TTCex Encoder Transmitter The TTCex module provides 10 optical outputs at a level of about 0 dBm each of which can be fanned out by a 1 32 optical tree coupler to broadcast to a total of 320 destinations The module contains 2 biphase mark encoders driven by a common internal VCXO PLL with very low jitter It can be operated as a single unit or in independent halves to feed 2 small partitions of up to 160 destinations each Outputs from the TTCex encoders are provided to drive extension TTCtx modules to broadcast to larger partitions The power consumption of the module is about 16W TTCtx Transmitter The TTCtx module is similar to the TTCex but has 14 optical outputs instead of 10 and does not contain any encoders It can be operated in independent halves to feed 2 small partitions of up to 224 destinations each or as a sing
6. check that they are fully home since the bayonet caps can be locked before they are completely inserted The mean optical signal level at each of the module outputs when transmitting the encoded TTC signal or the 40 08 MHz clock is typically 1 0 dBm 1 5 dBm The port to port insertion loss of the TTCoc 1 32 optical tree couplers see Fig 12 is typically in the range 14 9 dB to 18 7 dB with a typical variation in the output levels from the 32 ports of a given coupler of less than 1 5 dB Te a oe le CEeeececreeceecete Fig 12 TTCoc 1 32 optical tree coupler When a TTC distribution system is configured low value e g 3 dB ST plug type optical attenuators should be inserted as necessary to ensure that the received signal does not overload the optical receivers used A mean signal level of 19 dBm 3 dB is optimal for a wide range of receivers such as the Agilent HFBR 2316T photodiode preamplifier Owing to the excellent uniformity of the optical tree couplers it is only necessary to insert a single attenuator at the root Optoelectronic receivers which are equipped with AGC such as the TrueLight TRR 1B43 000 photodiode preamplifier have a large dynamic range and the use of such fine level adjusting attenuators is unnecessary Optical attenuators In order to allow for the overall insertion loss splitting loss excess loss of 1 32 optical tree couplers the power level at each of the outputs of TTCex TTC
7. h In applications in which greater timing jitter is acceptable it can also be driven by the encoder output of a TTCvx module The TTCtx can also accept the daisy chain output from another TTCtx module which is configured for Single operation or the 40 08 MHz clock output from a TTCcf module if the TTCtx is being used only for clock distribution When the module is configured in Single mode the I P socket is associated with all the optical outputs 1 to 14 When the module is in Dual mode it is associated with the lower group of outputs 8 to 14 The I O Lemo socket on the TTCtx front panel is an input or an output according to the configuration of the module When the module is in Single mode the socket provides a buffered output of the input signal for daisy chaining to additional TTCtx modules When the module is in Dual mode it becomes an input socket for the signal associated with the upper group of optical outputs 1 to 7 External clock The TTC system is designed to continue to deliver a 40 08 MHz clock even when parts of the distribution system are inoperative Of course this clock is only synchronised with the LHC bunch crossings when the full timing distribution chain is operational and at other times it serves only to keep the electronics at the experiments running If the central Faraday Cage timing generators are down the clock is generated at the PCR transmitter If the PCR transmitter is off it is generated by the local TTCmi at the
8. hown in Figures 3 and 4 All inputs and outputs are ECL swing 50 ohm AC coupled except for the A and B channel inputs to the TTCex which are DC coupled Fig 3 TTCex I O Fig 4 TTCtx I O On the TTCex front panel O indicates an output and T an input socket When the module is configured for Single operation the signals CLK1 ENC1 A1 and B1 are associated with all the optical outputs 1 to 10 and the CLK2 ENC2 A2 and B2 sockets are not used When the module is configured for Dual operation the signals CLK1 ENC1 Al and B1 are associated with the lower group of optical outputs numbered 6 to 10 while the signals CLK2 ENC2 A2 and B2 are associated with the upper group of optical outputs 1 to 5 One of the 40 08 MHz LHC bunch clock outputs from the TTCcf modules in the TTCmi machine interface crate of the experiment is connected to the CLK input socket of each TTCex The clock outputs from the TTCex internal VCXO are provided at the CLK1 and CLK2 sockets which should be linked to the CLOCK IN sockets of the associated TTCvi modules The CHANNEL A and B outputs from the TTCvi modules should be connected to the A1 B1 and A2 B2 inputs of the TTCex The TTCtx module has only two front panel Lemo connectors The I P socket is for the input of the encoded TTC signal from the ENC1 or ENC2 output sockets of a TTCex or the encoder in a TTCmi TTC minicrate or TTC high power transmitter crate or the output of a readout supervisor switc
9. le unit to feed a total of 448 destinations An electrical output is provided to allow several TTCtx modules to be daisy chained to broadcast to even larger partitions Since TTCtx modules do not contain encoders they must be driven by a TTCex module or by the encoder in a TTCmi TTC minicrate TTC high power transmitter crate or the output of an LHCb readout supervisor switch The power consumption of the module is about 10W Fig 2 TTCmx laser transmitter module TTCmx Transmitter A 3U high version of the TTCtx laser transmitter module is also available for optional use in TTCmi or TTC transmitter minicrates and in TTC repeaters for the LHC machine beam instrumentation This TTCmx module Fig 2 provides 4 optical outputs at a level of about 0 dBm which can be fanned out by 1 32 tree couplers to feed a total of 128 destinations In other respects including the electrical daisy chain output for larger numbers of destinations the TTCmx is similar to a TTCtx module TTCmx modules are normally driven by the encoder in the TTCmi or TTC transmitter minicrate or by the optical receiver in a TTC repeater In experiments such as ALICE in which the local trigger crates are located remotely from the CTP TTCmx modules may be used to broadcast the 40 08 MHz bunch clock to them from the TTCmi crate to avoid ground offset or crosstalk problems Electrical I O connections The front panel Lemo I O connectors of the TTCex and TTCtx modules are s
10. nimum hold time of Ah 3 4 ns after it See Fig 11 Outside this interval the A data input signal is a Don t care It should be noted that the LLA lt 0 gt input of the TTCvi is AC coupled which could result in a level shift at high data rates The maximum L1A signal duration should therefore be chosen to avoid significant DC offset at the highest trigger rate VCXO phase The TTCex has an internal VCXO phase adjustment Please don t touch it as it is set up on a test bench and if you have a problem twiddling this adjustment is sure to get you in deeper trouble Because the phase is set up in a standard way it is not necessary to make phase adjustments if you exchange one TTCex module for another Optical outputs The TTCex TTCtx and TTCmx modules are equipped with precision beryllium copper sleeved nickel plated zinc front panel sockets for industry standard ST PC keyed bayonet optical connectors such as 3M Dorran Type FO 6105 Index matching gel should not be used Note that a tiny dust particle or other contaminant can completely block the optical output and the protective caps supplied should be kept on any unused optical outputs Don t touch the ends of the ferrules with fingers or allow them to trail on the floor Impregnated optical instrument tissues such as Kodak lens cleaning paper are recommended for cleaning When the ST receptacles are new the connector ferrules can be quite stiff In case of low optical signal level
11. ons for the TTCtx Fig 7 TTCtx in Single mode Fig 8 TTCtx in Dual mode All the transmitter modules are fitted with non hermetic EMI shields held by press studs To access the jumpers in either module carefully remove the shield by prising it from its 6 mounting studs Be careful not to damage the delicate internal optical fibres while the module is unprotected TTCvi BC Delay adjustment The TTCvi modules associated with each TTCex receive the 40 08 MHz clock from the CLK1 and CLK2 outputs of the module The TTCvi internally delays this clock by an adjustable time in order that the phases of the internally generated A and B channel signals which it delivers to the TTCex can be set correctly taking into account the propagation delays of the interconnecting coaxial cables This clock delay is adjusted by the BC Delay rotary switch at the top of the front panel of the TTCvi see Fig 9 which should be set when the TTCvi is initially installed or if the lengths of any of the cables connecting it to the TTCex are changed AE a L a ee BS ial Fig 9 BC Delay switch To set the BC Delay switch insert Lemo Y adapters at the CLK1 or CLK2 output and the appropriate A and B data input sockets of the TTCex to allow these signals to be monitored with a scope probe Program a VME loop so that the TTCvi generates internal triggers at a high rate and adjust the switch such that the signal transitions on the data channels occur
12. tx and TTCmx transmitter modules is about 100 times that required by a single receiver Fig 13 20 dB optical attenuator If an output is connected directly to a single receiver for test purposes a 20 dB optical attenuator Fig 13 should be inserted at the transmitter output to avoid overloading Because of modal distribution factors not all attenuator technologies are appropriate for this application Suitable attenuators are available from Bruce Taylor When making optical signal level measurements in the TTC systems with a multi wavelength power meter it is important to ensure that the instrument calibration for 1310 nm is selected Many such instruments also require to be zeroed with the optical input connector capped before making accurate absolute power measurements Optical fibre All the optical transmitter outputs are intended for operation with ordinary 50 125 pm eraded index multimode fibre with a numerical aperture of 0 2 and a minimum bandwidth of 400 MHz km at 1300 nm Fibre attenuation at this wavelength is typically less than 3 dB km For safety reasons only fibre with a Low Smoke Zero Halogen LSZH sheath should be used although if you employ hot melt connectors you may find the low melting point of such material an inconvenience Optical fibre purchase requisitions at CERN are controlled to enforce the LSZH requirement and if you bring PVC sheathed fibre to CERN it may not be permitted at the LHC Ready connectorized
13. velength is 1280 1330 nm and the spectral width at 20 dBm is less than 4 nm They are ITU T G 957 compliant except for the higher mean launched power The laser diodes have temperature compensated bias and modulation current control and the output of a rear facet monitor is used to maintain constant optical output level against temperature changes and device aging Monitoring of the laser bias current and rear facet light output is possible internally to the modules for test purposes Extinction ratio typically exceeds 13 dB Laser replacement Although lifetime data are not available for the laser transmitters one TTCtx has been operating continuously for well over 12 months without measurable degradation of the signal levels or timing jitter of any of the 14 optical outputs All the lasers are mounted in sockets and should one fail it can easily be replaced The ESD threshold on all pins is 1000v The lasers are fitted with a non standard short pigtail and it should be noted that there is a special insulator film between each laser and its socket Before insertion the package pins are trimmed precisely using a jig The lasers themselves carry individual serial numbers and have a 12 month warranty Support contact In case of any problems with TTCex TTCtx or TTCmx modules contact Bruce Taylor CERN EP Bruce Taylor cern ch Tel 4122 767 3420 TTC website http ttc web cern ch TTC intro html In order to ensure that maintenance will be
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