afct-5971lz/alz single mode laser small form factor fast ethernet transceivers data sheet description the afct-5971lz/alz are high performance, cost ef - fective modules for serial optical data communications applications specifed for a signal rate of 125 mbd. they are designed for fast ethernet applications and are also compatible with the efm baseline 100-base-lx10 stan - dard over dual single mode fber. all modules are designed for single mode fber and operate at a nominal wavelength of 1300 nm. they in - corporate high performance, reliable, long wavelength optical devices and proven circuit technology to give long life and consistent service. the transmitter section of the afct-5971lz/alz incor - porates a 1300 nm fabry perot (fp) laser. the transmit - ter has full iec 825 and cdrh class 1 eye safety. the receiver section uses an movpe grown planar pin photodetector for low dark current and excellent re - sponsivity. a pseudo-ecl compatible logic interface simplifes in - terface to external circuitry. these transceivers are supplied in the new industry standard 2 x 5 dip style package with the lc fber con - nector interface and is footprint compatible with sff multi source agreement (msa). features ? multisourced 2 x 5 package style with lc receptacle ? single +3.3 v power supply ? temperature range: afct-5971lz: 0 c to +70 c AFCT-5971ALZ: -40c to +85c ? wave solder and aqueous wash process compatible ? manufactured in an iso9002 certifed facility ? fully class 1 cdrh/iec 825 compliant ? ieee 802.3ah standard compliant ? rohs compliant ? lvpecl compatible signal detect output ? designed for efm (ethernet in the first mile) baseline 100-base-lx10 performance over dual single mode fber applications ? ethernet in the first mile ? fast ethernet
2 data data lvpecl input laser modulator fp laser laser bias driver laser bias control photodiode (rear facet monitor) figure 1. receiver block diagram trans- impedance pre- amplifier filter gnd amplifier lvpecl output buffer lvpecl output buffer data out signal detect circuit sd data out figure 2. simplifed transmitter schematic functional description transmitter section design a schematic diagram for the transmitter is shown in fig - ure 2. the afct-5971lz/alz incorporates an fp laser as its optical source. all part numbers have been designed to be compliant with iec 825 eye safety requirements under any single fault condition and cdrh under nor - mal operating conditions. the optical output is con - trolled by a custom ic that detects the laser output via the monitor photodiode. this ic provides both dc and ac current drive to the laser to ensure correct modula - tion, eye diagram and extinction ratio over temperature, supply voltage and operating life. functional description receiver section design the receiver section for the afct-5971lz/alz con - tains an ingaas/inp photo detector and a preamplifer mounted in an optical subassembly. this optical subas - sembly is coupled to a postamp/decision circuit on a circuit board. the design of the optical assembly is such that it provides better than 14 db optical return loss (orl). the postamplifer is ac coupled to the preamplifer as illustrated in figure 1. the coupling capacitors are large enough to pass the efm test pattern at 125 mbd with - out signifcant distortion or performance penalty. figure 1 also shows a flter function which limits the bandwidth of the preamp output signal. the flter is de - signed to bandlimit the preamp output noise and thus improve the receiver sensitivity. these components will reduce the sensitivity of the re - ceiver as the signal bit rate is increased above 155 mb/s. noise immunity the receiver includes internal circuit components to flter power supply noise. however under some condi - tions of emi and power supply noise, external power supply fltering may be necessary (see application sec - tion). the signal detect circuit the signal detect circuit works by sensing the level of the received signal and comparing this level to a refer - ence. the sd output is low voltage pecl.
3 figure 3. block diagram package the overall package concept for these devices consists of the following basic elements; two optical subas - semblies, a electrical subassembly and the housing as illustrated in the block diagram in figure 3. the package outline drawing and pin out are shown in figures 4 and 5. the details of this package outline and pin out are compliant with the mult i source defnition of the 2 x 5 dip. the low profle of the avago technologies transceiver design complies with the maximum height allowed for the lc connector over the entire length of the package. the electrical subassembly consists of high volume multilayer printed circuit board on which the ic and various surface-mounted passive circuit elements are attached. the optical subassemblies are attached to the electrical subassembly. these two units are then ftted within the outer housing of the transceiver. the housing is then encased with a metal emi protective shield. the electrical subassembly carries the signal pins that exit from the bottom of the transceiver. the solder posts are designed to provide the mechanical strength required to withstand the loads imposed on the trans - ceiver by mating with the lc connectored fber cables. although they are not connected electrically to the transceiver, it is recommended to connect them to chassis ground. data out signal detect data in data in tx disable quantizer ic laser driver and control circuit pin photodiode preamplifier subassembly laser optical subassembly data out lc receptacle r x supply t x supply r x ground t x ground laser bias monitoring laser diode modulator case note note: nose clip provides connection to chassis ground for both emi and thermal dissipation.
4 figure 4. afct-5971lz/alz package outline drawing top view bottom view side view g module - no emi shield side view front view back view dimensions in millimeters (inches) dimensions shown are nominal. all dimensions meet the maximum package outline drawing in the sff msa.
5 special assembly notes: a) the label is attached on top of the metal housing. b) external nose shield is included. top view & label location bottom view & label location label instructions: product label format barcode label format a) product label: ? china is the country of manufacturing. ? yyww is year and workweek. ? is tuv symbol. b) barcode label: ? acddeefxxxx - ac is afct product prefx - ddee is year and workweek of barcode label - f is sff product identifer - xxxx is 4 alphanumeric no in running sequence. ? marking is done by labeling on the module. label location refer to special assembly notes .
� pin descriptions: pin 1 receiver signal ground v ee rx: directly connect this pin to the receiver ground plane. pin 2 receiver power supply v cc rx: provide +3.3 v dc via the recommended receiver power supply flter circuit. locate the power supply flter cir - cuit as close as possible to the v cc rx pin. note: the flter circuit should not cause v cc to drop below minimum specifcation. pin 3 signal detect sd: normal optical input levels to the receiver result in a logic 1 output. low optical input levels to the receiver result in a logic 0 output. this signal detect output can be used to drive a lvpecl input on an upstream circuit, such as signal detect in - put or loss of signal-bar. pin 4 receiver data out bar rd-: no internal terminations are provided. see recommend - ed circuit schematic. pin 5 receiver data out rd+: no internal terminations are provided. see recommend - ed circuit schematic. connection diagram figure 5. pin out diagram (top view) transmitter data in ba r transmitter data in transmitter disabl e transmitter signal ground transmitter power suppl y rx tx o o o o o 1 2 3 4 5 o o o o o 10 9 8 7 6 receiver signal ground receiver power suppl y signal detect receiver data out ba r receiver data ou t to p view mounting studs/ solder posts pin 6 transmitter power supply v cc tx: provide +3.3 v dc via the recomme n ded transmitter power supply flter circuit. locate the power supply fl - ter circuit as close as possible to the v cc tx pin. pin 7 transmitter signal ground v ee tx: directly connect these pins to the transmitter signal ground plane. pin 8 transmitter disable t dis : optional feature, connect this pin to +3.3 v ttl logic high 1 to disable module. to enable module connect to ttl logic low 0. pin 9 transmitter data in td+: no internal terminations are provided. see recommend - ed circuit schematic. pin 10 transmitter data in bar td-: no internal terminations are provided. see recommend - ed circuit schematic. mounting studs/solder posts the two mounting studs are provided for transceiver mechanical attachment to the circuit board. it is rec - ommended that the holes in the circuit board be con - nected to chassis ground.
7 figure 6a. recommended dc coupled interface circuit o v ee r x o v cc r x o sd o rd- o rd+ z = 50 ? z = 50 ? z = 50 ? z = 50 ? sd v cc (+3.3 v ) v cc (+3.3 v ) rd + rd - z = 50 ? 1 td- o td + o t di s o v ee t x o v cc t x o 1 h c2 1 h c1 c3 10 f t x r x 130 ? 130 ? 130 ? 130 ? terminate a t transceiver inputs 100 ? t dis (lvttl ) 2 3 4 5 10 9 8 7 6 td - td + lvpecl v cc (+3.3 v ) 100 ? c4 * 10 f 82 ? c5 * 10 f lvpecl 130 ? v cc (+3.3 v ) terminate a t device inputs phy device note: c1 = c2 = c3 = 10 nf or 100 n f * c4 and c5 are optional bypass capacitors for additional low frequency noise filtering. application information the applications engineering group at avago tech - nologies is available to assist you with technical under - standing and design trade-ofs associated with these transceivers. you can contact them through your avago sales representative. the following information is provided to answer some of the most common questions about the use of the parts. optical power budget and link penalties the worst-case optical power budget (opb) in db for a fber-optic link is determined by the diference between the minimum transmitter output optical power (dbm avg) and the lowest receiver sensitivity (dbm avg). this opb provides the necessary optical signal range to es - tablish a working fber-optic link. the opb is allocated for the fber-optic cable length and the corresponding link penalties. for proper link performance, all penalties that afect the link performance must be accounted for within the link optical power budget. electrical and mechanical interface recommended circuit figures � a and � b show recommended dc and ac coupled circuits for deploying the avago technologies transceivers in +3.3 v systems. data line interconnections avago technologies afct-5971lz/alz fiber-optic transceivers are designed to couple to +3.3 v pecl sig - nals. the transmitter driver circuit regulates the output optical power. the regulated light output will maintain a constant output optical power provided the data pat - tern is reasonably balanced in duty cycle. if the data duty cycle has long, continuous state times (low or high data duty cycle), then the output optical power will gradually change its average output optical power level to its preset value.
8 figure 6b. recommended ac coupled interface circuit the afct-5971lz/alz have a transmit disable function which is a single-ended +3.3 v ttl input which is dc- coupled to pin 8. as for the receiver section, it is internally ac-coupled between the preamplifer and the postamplifer stages. the actual data and data-bar outputs of the postampli - fer are dc-coupled to their respective output pins (pins 4, 5). the two data outputs of the receiver should be terminated with identical load circuits. signal detect is a single-ended, +3.3 v pecl compatible output signal that is dc-coupled to pin 3 of the module. signal detect should not be ac-coupled externally to the follow-on circuits because of its infrequent state changes. power supply filtering and ground planes it is important to exercise care in circuit board layout to achieve optimum performance from these transceiv - ers. figures � a and � b show the power supply circuit which complies with the small form factor multisource agreement. it is further recommended that a continu - ous ground plane be provided in the circuit board di - rectly under the transceiver to provide a low inductance ground for signal return current. this recommendation is in keeping with good high frequency board layout practices. package footprint and front panel considerations the avago technologies transceivers comply with the circuit board common transceiver footprint hole pattern defned in the current multisource agreement which defned the 2 x 5 package style. this drawing is reproduced in figure 7 with the addition of ansi y14.5m compliant dimensioning to be used as a guide in the mechanical layout of your circuit board. figure 8 shows the front panel dimensions associated with such a layout. eye safety circuit for an optical transmitter device to be eye-safe in the event of a single fault failure, the transmit-ter must ei - ther maintain eye-safe operation or be disabled. o v ee r x o v cc r x o sd o rd- o rd+ z = 50 w z = 50 w z = 50 w z = 50 w sd lvpecl v cc (+3.3 v) v cc (+3.3 v) rd+ rd- v cc (+3.3 v) 130 w z = 50 w 1 td- o td+ o t dis o v ee t x o v cc t x o 1 h c2 1 h c1 c3 10 f t x r x 130 w 130 w 130 w 130 w 100 nf 100 nf 100 nf 100 nf 82 w 130 w v cc (+3.3 v) 130 w 82 w t dis (lvttl) 2 3 4 5 10 9 8 7 6 td- td+ note: c1 = c2 = c3 = 10 nf or 100 nf note a: circuit assumes open emitter output note b: when internal bias is provided replace split resistors with 100 w termination * c4 and c5 are optional bypass capacitors for additional low frequency noise filtering. note a note b v cc (+3.3 v) 100 nf 100 nf 82 w 130 w v cc (+3.3 v) 82 w 130 w c4 * 10 f 82 w 100 nf c5 * 10 f
9 figure 7. recommended board layout hole pattern 7.59 (0.299) 3 (0.118) 3 (0.118) 6 (0.236) 4.57 (0.18) 4 x 1.78 (0.07) 10 x ? 0.81 0.1 (0.032 0.004) 3.08 (0.121) 2 x ? 2.29 (0.09) 9.59 (0.378) 2 (0.079) 13.34 (0.525) 7.11 (0.28) 4 x ? 1.4 0.1 (0.055 0.004) 2 x ? 1.4 0.1 (0.055 0.004) 2 x ? 1.4 0.1 (0.055 0.004) 10.16 (0.4 ) 3.56 (0.14) 2 x ? 2.29 max. (0.09) 17.8 (0.700) 2 (0.079) *4 *5 dimensions in millimeters (inches) notes: 1. this figure describes msa recommended circuit board layout for the sff transceiver. 2. the hatched areas are keep-out areas reserved for housing standoffs. no metal traces or ground connection in keep-out areas. 3. 2 x 5 transceiver module requires 16 pcb holes (10 i/o pins, 2 solder posts and 4 optional package grounding tabs). package grounding tabs should be connected to signal ground. *4. the mounting studs should be soldered to chassis ground for mechanical integrity and to ensure footprint compatibility with other sff transceivers. *5. holes for optional housing leads must be tied to signal ground. the afct-5971lz/alz is intrinsically eye safe and does not require shut down circuitry. signal detect the signal detect circuit provides a deasserted output signal when the optical link is broken (or when the re - mote transmitter is off). the signal detect threshold is set to transition from a high to low state between the minimum receiver input optical power and -45 dbm avg. input optical power indicating a defnite optical fault (e.g. unplugged connector for the receiver or transmitter, broken fber, or failed far-end transmitter or data source). the signal detect does not detect receiver data error or error-rate. data errors can be determined by signal processing ofered by upstream phy ics. electromagnetic interference (emi) one of a circuit board designers foremost concerns is the control of electromagnetic emissions from electron - ic equipment. success in controlling generated electro - magnetic interference (emi) enables the designer to pass a governmental agencys emi regulatory standard and more importantly, it reduces the possibility of interfer - ence to neighboring equipment. avago technologies has designed the afct-5971lz/alz to provide excel - lent emi performance. the emi performance of a chassis is dependent on physical design and features which help improve emi suppression. avago technologies en - courages using standard rf suppression practices and avoiding poorly emi-sealed enclosures. avago technologies lc transceivers (afct-5971lz/alz) have nose shields which provide a convenient chassis connection to the nose of the transceiver. this nose shield improves system emi performance by effec - tively closing of the lc aperture. the recommended transceiver position, pcb layout and panel opening for these devices are the same, making them mechanically drop-in compatible. figure 8 shows the recommended positioning of the transceivers with respect to the pcb and faceplate.
10 figure 8. recommended panel mounting 15.24 (0.6) dimensions in millimeters (inches) 1. figure describes the recommended front panel opening for a lc or sg sff transceiver. 2. sff transceiver placed at 15.24 mm (0.6) min. spacing. 14.22 0.1 (0.56 0.004) 10.16 0.1 (0.4 0.004) detail a top of pcb 1 (0.039) a solder posts 15.75 max. 15.0 min. (0.62 max. 0.59 min.) section b - b 15.24 (0.6) b b lc sff cleaning recommendations in the event of contamination of the optical ports, the recommended cleaning process is the use of forced nitrogen. if contamination is thought to have remained, the optical ports can be cleaned using a ntt interna - tional cletop stick type (diam. 1.25 mm) and hfe7100 cleaning fuid. regulatory compliance the regulatory compliance for transceiver performance is shown in table 1. the overall equipment design will determine the certifcation level. the transceiver perfor - mance is ofered as a fgure of merit to assist the design - er in considering their use in equipment designs. recommended cleaning/degreasing chemicals alcohols: methyl, isopropyl, isobutyl. aliphatics: hexane, heptane other: naphtha. do not use partially halogenated hydrocarbons such as 1,1.1 trichloroethane, ketones such as mek, acetone, chloroform, ethyl acetate, methylene dichloride, phenol, methylene chloride, or n-methylpyrolldone. also, avago technologies does not recommend the use of cleaners that use halogenated hydrocarbons because of their potential environmental harm. recommended solder and wash process the afct-5971lz/alz are compatible with industry- standard wave solder processes. process plug this transceiver is supplied with a process plug for protection of the optical port within the lc connector receptacle. this process plug prevents contamination during wave solder and aqueous rinse as well as during handling, shipping and storage. it is made of a high- temperature, molded sealing material that can with - stand +85c and a rinse pressure of 110 lbs per square inch. the process plug should only be used once. after removing it from the transceiver, it must not be used again as a process plug; however, if it has not been contaminated it can be reused as a dust cover. recommended solder fuxes solder fuxes used with the afct-5971lz/alz should be water-soluble, organic fuxes. recommended solder fuxes include lonco 3355-11 from london chemical west, inc. of burbank, ca, and 100 flux from alpha- metals of jersey city, nj.
11 table 1: regulatory compliance - targeted specifcation feature test method performance electrostatic discharge (esd) to the electrical pins mil-std-883 method 3015 class 1 (>500 v). electrostatic discharge (esd) to the lc receptacle variation of iec �1000-4-2 tested to 8 kv contact discharge. electromagnetic interference (emi) fcc class b margins are dependent on customer board and chassis designs. immunity variation of iec �1000-4-3 typically show no measurable efect from a 10 v/m feld swept from 27 to 1000 mhz applied to the transceiver without a chassis enclosure. laser eye safety and equipment type testing fda cdrh 21-cfr 1040 class 1 iec �0825-1 amendment 2 2001-01 accession number: 9521220-133 license number: 933/21203530/05 component recognition underwriters laboratories and canadian standards association joint component recognition for informa - tion technology equipment includ - ing electrical business equipment. ul file number: e173874 electrostatic discharge (esd) there are two design cases in which immunity to esd damage is important. the frst case is during handling of the transceiver prior to mounting it on the circuit board. it is important to use normal esd handling precautions for esd sensitive de - vices. these pr e cautions include using grounded wrist straps, work benches, and foor mats in esd controlled areas. the second case to consider is static discharges to the exterior of the equipment chassis containing the trans - ceiver parts. to the extent that the lc connector recep - tacle is exposed to the outside of the equipment chassis it may be subject to whatever system-level esd test cri - teria that the equipment is intended to meet. electromagnetic interference (emi) most equipment designs utilizing these high-speed transceivers from avago technologies will be required to meet fcc regulations in the united states, cenelec en55022 (cispr 22) in europe and vcci in japan. refer to emi section (page 9) for more details. immunity transceivers will be subject to radio-frequency elec - tromagnetic fields following the iec � 1000-4-3 test method. eye safety these laser-based transceivers are classifed as ael class i (u.s. 21 cfr(j) and ael class 1 per en � 0825-1 (+a11). they are eye safe when used within the data sheet limits per cdrh. they are also eye safe under normal operat - ing conditions and under all reasonably foreseeable single fault conditions per en � 0825-1. avago technolo - gies has tested the transceiver design for compliance with the requirements listed below under normal operating conditions and under single fault conditions where applicable. tuv rheinland has granted certifca - tion to these transceivers for laser eye safety and use in en � 0825-2 applications. their performance enables the transceivers to be used without concern for eye safety up to 3.5 v transmitter v cc . caution: there are no user serviceable parts nor any mainte - nance required for the afct-5971lz/alz. all adjust - ments are made at the factory before shipment to our customers. tampering with or modifying the perform - ance of the parts will result in voided product warranty. it may also result in improper operation of the circuitry, and possible overstress of the laser source. device deg - radation or product failure may result. connection of the devices to a non-approved optical source, operating above the recommended absolute maximum conditions or operating the afct-5971lz/ alz in a manner inconsistent with its design and func - tion may result in hazardous radiation exposure and may be considered an act of modifying or manufac - turing a laser product. the person(s) performing such an act is required by law to recertify and reidentify the laser product under the provisions of u.s. 21 cfr (subchapter j).
absolute maximum ratings stresses in excess of the absolute maximum ratings can cause catastrophic damage to the device. limits apply to each parameter in isolation, all other parameters having values within the recommended operating conditions. it should not be assumed that limiting values of more than one parameter can be applied to the product at the same time. exposure to the absolute maximum ratings for extended periods can adversely afect device reliability. parameter symbol min. typ. max. unit reference wave soldering temp/time aqueous wash t sold /t sold p +2�0/10 110 c/sec psi storage temperature t s -40 +85 c supply voltage v cc -0.5 3.� v data input voltage v i -0.5 v cc v data output current i d 50 ma relative humidity rh 85 % parameter symbol min. typ. max. unit reference ambient operating temperature afct-5971lz AFCT-5971ALZ t a t a 0 -40 +70 +85 c c 1 1 supply voltage v cc 3.1 3.5 v 2 power supply noise rejection psnr 100 mv p-p 3 transmitter diferential input voltage v d 0.3 1.� v data output load r dl 50 w transmit disable input voltage - low t dis 0.� v transmit disable input voltage - high t dis 2.2 v transmit disable assert time t assert 10 s 4 transmit disable deassert time t deassert 1.0 ms 5 parameter symbol min. typ. max. unit reference supply current i cct 57 140 ma power dissipation p dist 0.5 w data input voltage swing (single-ended) v ih - v il 250 930 mv transmitter diferential data input current - low i il -350 a transmitter diferential data input current - high i ih 350 a notes: 1. ambient operating temperature utilizes air fow of 2 ms -1 over the device. 2. the transceiver is class 1 eye safe up to v cc = 3.5 v. 3. tested with a sinusoidal signal in the frequency range from 10 hz to 1 mhz on the v cc supply with the recommended power supply flter in place. typically less than a 1 db change in sensitivity is experienced. 4. time delay from transmit disable assertion to laser shutdown. 5. time delay from transmit disable deassertion to laser startup. transmitter electrical characteristics afct-5971lz: t a = 0 c to +70 c, v cc = 3.1 v to 3.5 v AFCT-5971ALZ: t a = -40 c to +85 c, v cc = 3.1 v to 3.5 v recommended operating conditions
13 transmitter optical characteristics afct-5971lz: t a = 0 c to +70 c, v cc = 3.1 v to 3.5 v) AFCT-5971ALZ: t a = -40c to +85 c, v cc = 3.1 v to 3.5 v) parameter symbol min. typ. max. unit reference output optical power 9 m smf p out -15 -8 dbm 10 center wavelength l c 12�1 13�0 nm spectral width - rms s 7.7 nm rms 11 optical rise time t r 2 ns 12 optical fall time t f 2 ns 12 extinction ratio e r � db output optical eye compliant with eye mask ieee 802.3ah- 2004 13 rin rin 12 (oma) -110 db/hz transmitter and dispersion penalty tdp 4.0 db optical return loss orl 12 db signalling speed 125-50 ppm 125+50 ppm mbd receiver electrical characteristics afct-5971lz: t a = 0 c to +70 c, v cc = 3.1 v to 3.5 v AFCT-5971ALZ: t a = -40c to +85 c, v cc = 3.1 v to 3.5 v parameter symbol min. typ. max. unit reference supply current i ccr 89 140 ma � power dissipation p disr 0.5 w data output voltage swing (single-ended) v oh - v ol 575 930 mv 7 data output rise time t r 2.2 ns 8 data output fall time t f 2.2 ns 8 signal detect output voltage - low v ol - v cc -1.84 -1.� v 9 signal detect output voltage - high v oh - v cc -1.1 -0.88 v 9 signal detect assert time (off to on) as max 100 s signal detect deassert time (on to off) ans max 2.3 100 s notes: �. includes current for biasing rx data outputs. 7. these outputs are compatible with low voltage pecl inputs. 8. these are 20-80% values. 9. sd is lvpecl compatible when terminated with 50 w to v cc -2 v.
parameter symbol min. typ. max. unit reference receiver sensitivity p in min -25 dbm avg. 14 receiver overload p in max -8 0 dbm avg. input operating wavelength l 12�1 1580 nm signal detect - asserted p a -39.8 -25 dbm avg. signal detect - deasserted p d -45 -41.9 dbm avg. signal detect - hysteresis p h 0.5 1.39 4 db notes: 10. the output power is coupled into a 1 m single mode fber. minimum output optical level is at end of life. 11. the relationship between fwhm and rms values for spectral width can be derived from the assumption of a gaussian shaped spectrum which results in rms = fwhm/2.35. 12. these are unfltered 10-90% values. 13. mask coordinates (x1, x2, x3, y1, y2, y3, y4) = (0.18, 0.29, 0.35, 0.35, 0.38, 0.4, 0.55). 14. minimum sensitivity for ieee 802.3ah test pattern with baseline wander. receiver optical characteristics afct-5971lz: t a = 0 c to +70 c, v cc = 3.1 v to 3.5 v) AFCT-5971ALZ: t a = -40c to +85 c, v cc = 3.1 v to 3.5 v)
ordering information 1300 nm fp laser (temperature range 0 c to +70 c, afct-5971lz = 2 x 5 lc connector, ir, lvpecl sd with emi nose shield 1300 nm fp laser (temperature range -40c to +85 c, AFCT-5971ALZ = 2 x 5 lc connector, ir, lvpecl sd with emi nose shield class 1 laser product: this product conforms to the applicable requirements of 21 cfr 1040 at the date of manufacture date of manufacture: avago technologies inc., no 1 yishun ave 7, singapore handling precautions 1. the afct-5971lz/alz can be damaged by current surges or overvoltage. power supply transient precautions should be taken. 2. normal handling precautions for electrostatic sensitive devices should be taken. for product information and a complete list of distributors, please go to our web site: www.avagotech.com avago, avago technologies, and the a logo are trademarks of avago technologies, limited in the united states and other countries. data subject to change. copyright ? 2006 avago technologies limited. all rights reserved. obsoletes av01-0207en av02-0638en - july 31, 2007
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