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| description the HFBR-5923AL from agilent technologies is a high performance, cost-effective optical transceiver for serial optical data communications applications operating at 2.125 gb/s and 1.25 gb/s. this module is designed for multimode fiber and operates at a nominal wavelength of 850 nm. the transceiver incorporates 3.3 v dc compatible technology including an 850 nm vcsel transmit- ter. the HFBR-5923AL offers maximum flexibility to fibre channel designers, manufacturers, and system integrators to implement a range of solutions for multi-mode fibre channel applications. this product is fully compatible with all equipment meeting the fibre channel fc-pi 200-m5-sn-i and 200-m6-sn-i 2.125 gbd specifications, and is compatible with the fibre channel fc-pi 100-m5-sn-i, fc-pi 100-m6- sn-i, fc-ph2 100-m5-sn- and fc- ph2 100-m6-sn-i 1.0625 gbd specifications. the HFBR-5923AL has been designed to work with cd laser legacy systems. the HFBR-5923AL is also compliant with the sff multi source agreement (msa). agilent HFBR-5923AL fibre channel 2.125/1.0625 gbd 850 nm small form factor pin through hole (pth) low voltage (3.3 v) optical transceiver data sheet features ? compatible with 2.125 gbd fibre channel fc-pi standard C fc-pi 200-m5-sn-i for 50/125 m m multimode cables C fc-pi 200-m6-sn-i for 62.5/125 m m multimode cables ? compatible with 1.0625 gbd vcsel operation for both 50/125 and 62.5/125 m m multimode cables ? compatible with vcsel and cd laser applications ? industry standard pin through hole (pth) package ? lc-duplex connector optical interface ? link lengths at 2.125 gbd: 0.5 to 300 m C 50/125 m m mmf 0.5 to 150 m C 62.5/125 m m mmf ? link lengths at 1.0625 gbd: 0.5 to 500 m C 50/125 m m mmf 0.5 to 300 m C 62.5/125 m m mmf ? reliable 850 nm vertical cavity surface emitting laser (vcsel) source technology ? laser ael class i (eye safe) per: us 21 cfr (j) en 60825-1 (+all) ? single +3.3 v power supply operation ? 2 x 5 dip package style with lc-duplex fiber ? wave solder and aqueous wash process compatible applications ? mass storage system i/o ? computer system i/o ? high speed peripheral interface ? high speed switching systems ? host adapter i/o ? raid cabinets related products ? hfbr-5602: 850 nm +5 v gigabit interface converter (gbic) for fiber channel fc-ph-2 ? hfbr-53d3: 850 nm +5 v 1 x 9 laser transceiver for fiber channel fc-ph-2 ? hfbr-5910e: 850 nm +3.3 v sff mtrj laser transceiver for fibre channel fc-ph-2 ? hdmp-2630/2631: 2.125/1.0625 gbps trx family of serdes ic ? hfbr-5720l: 850 nm 3.3 v 2.125/ 1.0625 gbps sfp transceiver
2 figure 1. transceiver functional diagram. see table 5 for process compatibility specifications. figure 2. module pin assignments and pin configuration. module package agilent offers the pin through hole package utilizing an integral lc-duplex optical interface con- nector. the transceiver uses a reliable 850 nm vcsel source and requires a 3.3 v dc power supply for optimal system design. module diagrams figure 1 illustrates the major functional components of the HFBR-5923AL. the connection diagram for both modules are shown in figure 2. figure 6 depicts the external configuration and dimensions of the module. installation the HFBR-5923AL can be in- stalled in any msa-compliant pin through hole port. the module pin description is shown in figure 2. solder and wash process capability these transceivers are delivered with protective process plugs inserted into the lc connector receptacle. this process plug protects the optical subassem- blies during wave solder and aqueous wash processing and acts as a dust cover during ship- ping. these transceivers are compatible with industry standard wave or hand solder processes. recommended solder fluxes solder fluxes used with the HFBR-5923AL should be water- soluble, organic fluxes. recom- mended solder fluxes include lonco 3355-11 from london chemical west, inc. of burbank, ca, and 100 flux from alpha- metals of jersey city, nj. recommended cleaning/degreasing chemicals alcohols: methyl, isopropyl, isobutyl. aliphatics: hexane, heptane. other: naphtha. do not use partially halogenated hydrocarbons such as 1,1.1 trichoroethane or ketones such as mek, acetone, chloroform, ethyl acetate, methylene dichloride, phenol, methylene chloride, or n-methylpyrolldone. also, agilent pin name type 1 2 3 4 5 6 7 8 9 10 rx ground rx power rx sd rx data bar rx data tx power tx ground tx disable tx data tx data bar ground power status out signal out signal out power ground control in signal in signal in pin description 6 7 8 9 10 rx 5 4 3 2 1 tx top view light from fiber optical interface light to fiber photo-detector receiver amplification & quantization rd+ (receive data) rd?(receive data) signal detect vcsel transmitter laser driver & safety circuitry tx_disable td+ (transmit data) td?(transmit data) tx_fault (available only on 2 x 6) electrical interface HFBR-5923AL block diagram 3 electrostatic discharge (esd) there are two conditions in which immunity to esd damage is im- portant. table 1 documents our immunity to both of these condi- tions. the first condition is during handling of the transceiver prior to attachment to the pcb. to pro- tect the transceiver, it is important to use normal esd handling pre- cautions. these precautions in- clude using grounded wrist straps, work benches, and floor mats in esd controlled areas. the esd sensitivity of the HFBR-5923AL is compatible with typical industry production environments. the second condition is static dis- charges to the exterior of the host equipment chassis after installa- tion. to the extent that the duplex lc optical interface is exposed to the outside of the host equipment chassis, it may be subject to system-level esd requirements. the esd performance of the HFBR-5923AL exceeds typical industry standards. immunity equipment hosting the HFBR-5923AL modules will be subjected to radio-frequency electromagnetic fields in some environments. the transceivers have good immunity to such fields due to their shielded design. electromagnetic interference (emi) most equipment designs utilizing these high-speed transceivers from agilent technologies will be required to meet the requirements of fcc in the united states, cenelec en55022 (cispr 22) in europe and vcci in japan. the metal housing and shielded design of the HFBR-5923AL minimize the emi challenge facing the host equipment designer. these trans- ceivers provide superior emi per- formance. this greatly assists the designer in the management of the overall system emi performance. does not recommend the use of cleaners that use halogenated hydrocarbons because of their potential environmental harm. transmitter section the transmitter section includes an 850 nm vcsel (vertical cavity surface emitting laser) light source and a transmitter driver circuit. the driver circuit maintains a constant optical power level provided that the data pattern is valid 8b/10b code. connection to the transmitter is provided via an lc optical connector. tx disable the HFBR-5923AL accepts a transmit disable control signal input which shuts down the trans- mitter. a high signal implements this function while a low signal allows normal laser operation. in the event of a fault (e.g., eye safety circuit activated), cycling this control signal resets the mod- ule. the tx disable control should be actuated upon initial iza- tion of the module. see figure 5 for product timing diagrams. eye safety circuit for an optical transmitter device to be eye-safe in the event of a single fault failure, the transmitter will either maintain normal, eye-safe operation or be disabled. in the event of an eye safety fault, the vcsel will be disabled. receiver section connection to the receiver is provided via an lc optical con- nector. the receiver bandwidth of this circuit enables the hfbr- 5923al to be compatible with both vcsel and cd laser applica- tions. this circuit also includes a signal detect (sd) circuit which provides an open collector logic low output in the absence of a usable input optical signal level. signal detect the signal detect (sd) output indicates if the optical input signal to the receiver does not meet the minimum detectable level for fibre channel compliant signals. when sd is low it indicates loss of signal. when sd is high it indicates normal operation. the signal detect thresholds are set to indicate a definite optical fault has occurred (e.g., disconnected or broken fiber connection to receiver, failed transmitter). functional data i/o agilents HFBR-5923AL fiber- optic transceiver is designed to accept industry standard differen- tial signals. in order to reduce the number of passive components required on the customers board, agilent has included the function- ality of the transmitter bias resis- tors and coupling capacitors within the fiber optic module. the transceiver is compatible with an ac-coupled configuration and is internally terminated. figure 1 depicts the functional diagram of the HFBR-5923AL. caution should be taken to account for the proper intercon- nection between the supporting physical layer integrated circuits and the HFBR-5923AL. figure 3 illustrates the recommended interface circuit. reference designs figure 3 depicts a typical applica- tion configuration, while figure 4 depicts the multisourced power supply filter circuit design. regulatory compliance see table 1 for transceiver regu- latory compliance performance. the overall equipment design will determine the certification level. the transceiver performance is offered as a figure of merit to assist the designer. 4 table 1. regulatory compliance feature test method performance electrostatic discharge (esd) mil-std-883c method 3015.4 class 2 (> 2000 v) to the electrical pins electrostatic discharge (esd) variation of iec 61000-4-2 typically withstand at least 25 kv without damage to the duplex lc receptacle when the duplex lc connector receptacle is contacted by a human body model probe. electromagnetic interference fcc class b system margins are dependent on customer (emi) cenelec en55022 class b board and chassis design. (cispr 22a) vcci class 1 immunity variation of iec 61000-4-3 typically shows a negligible effect from a 10 v/m field swept from 80 to 1000 mhz applied to the transceiver without a chassis enclosure. eye safety us fda cdrh ael class 1 cdrh file 9720151 en(iec)60825-1,2, tuv file r2079009 en60950 class 1 component recognition underwriters laboratories and ul file e173874 canadian standards association joint component recognition for information technology equipment including electrical business equipment. eye safety these 850 nm vcsel-based transceivers provide class 1 eye safety by design. agilent technologies has tested the transceiver design for compliance with the requirements listed in table 1: regulatory compliance, under normal operating condi- tions and under a single fault condition. flammability the HFBR-5923AL vcsel trans- ceiver housing is made of metal and high strength, heat resistant, chemically resistant, and ul 94v-0 flame retardant plastic. caution there are no user serviceable parts nor is any maintenance required for the HFBR-5923AL. all adjustments are made at the factory before shipment to our customers. tampering with or modifying the performance of the HFBR-5923AL will result in voided product warranty. it may also result in improper operation of the HFBR-5923AL circuitry, and possible overstress of the laser source. device degradation or product failure may result. connection of the HFBR-5923AL to a non- approved optical source, operating above the recom- mended absolute maximum con- ditions or operating the HFBR-5923AL in a manner in- consistent with its design and function may result in hazardous radiation exposure and may be considered an act of modifying or manufacturing a laser product. the person(s) performing such an act is required by law to re- certify and re-identify the laser product under the provisions of u.s. 21 cfr (subchapter j) and the tuv. ordering information please contact your local field sales engineer or one of agilent technologies franchised distribu- tors for ordering information. for technical information regarding this product, including the msa, please visit agilent technologies semiconductors products website at www.agilent.com/view/fiber. use the quick search feature to search for this part number. you may also contact agilent tech- nologies semiconductor products customer response center at 1-800-235-0312. 5 figure 3. typical application configuration. figure 4. msa recommended power supply filter. 1 ? 1 ? 0.1 ? v cc r sff module 10 ? v cc t 0.1 ? 10 ? 3.3 v host board 0.1 ? note: inductors must have less than 1 w series resistance per msa. laser driver & safety circuitry 50 w 50 w so+ so� amplification & quantization 50 w 50 w si+ si� vrefr vrefr tbc ewrap rbc rx_rate rx_sd refclk tbc ewrap rbc rx_rate refclk tx[0:9] rx[0:9] tx_disable td+ td� tx gnd rx gnd 3.3 v 106.25 mhz protocol ic v cc ,t 1 ? 1 ? 10 ? 0.1 ? 3.3 v v cc ,r 4.7 k to 10 k 10 ? 0.1 ? 0.1 ? hdmp-2630/31 9.0 k rd+ rd� rx_sd 100 k 0.01 ? 0.01 ? 100 k 0.01 ? 0.01 ? gp04 HFBR-5923AL note: tx_fault required for 2 x 6 module only. 1.2 k v cc ,r 6 table 2. pin description pin name function/description msa notes 1v ee r receiver ground 1 2v cc r receiver power C3.3 v 5% 5 3 sd signal detect C low indicates loss of signal 3 4 rdC inverse received data out 4 5 rd+ received data out 4 6v cc t transmitter power C3.3 v 5% 5 7v ee t transmitter ground 1 8 tx disable transmitter disable C module disables on high 2 9 td+ transmitter data in 6 10 tdC inverse transmitter data in 6 notes: 1. transmitter and receiver ground are common in the internal module pcb. they are electrically connected to signal ground within the module, and to the housing shield (see note 5 in figure 7c). this housing shield is electrically isolated from the nose shield which is connected to chassis ground (see note 4 in figure 7c). 2. tx disable input is used to shut down the laser output per the state table below. it is pulled down internally within the module with a 9.0 k w resistor. low (0 C 0.8 v): transmitter on between (0.8 v and 2.0 v): undefined high (2.0 C 3.465 v): transmitter disabled open: transmitter enabled 3. sd (signal detect) is a normally high lvttl output. when high it indicates that the received optical power is adequate for normal operation. when low, it indicates that the received optical power is below the worst case receiver sensitivity, a fault has occurred, and the link is no longer valid. 4. rd-/+: these are the differential receiver outputs. they are ac coupled 100 w differential lines which should be terminated with 100 w differential at the user serdes. the ac coupling is done inside the module and is thus not required on the host board. the voltage swing on these lines will be between 400 and 2000 mv differential (200 C 1000 mv single ended) when properly terminated. these levels are compatible with cml and lvpecl voltage swings. 5. v cc r and v cc t are the receiver and transmitter power supplies. they are defined as 3.135 C 3.465 v at the pth connector pin. the maximum supply current is 200 ma. 6. td-/+: these are the differential transmitter inputs. they are ac coupled differential lines with 100 w differential termination inside the module. the ac coupling is done inside the module and is thus not required on the host board. the inputs will accept differential swings of 400 C 2400 mv (200 C 1200 mv single ended), though it is recommended that values between 400 and 1200 mv differential (200 C 600 mv single ended) be used for best emi performance. these levels are compatible with cml and lvpecl. 7 table 5. process compatibility parameter symbol minimum maximum unit notes hand lead solder temperature/time t sold /t sold +260/10 c/sec wave solder and aqueous wash t sold /t sold +260/10 c/sec 1 note: 1. aqueous wash pressure < 110 psi. table 3. absolute maximum ratings parameter symbol minimum typical maximum unit notes storage temperature t s C40 +100 ?c 1 case temperature t c 0 +85 ?c 1, 2 relative humidity rh 5 95 % 1 supply voltage v cc t,r C0.5 4 v 1, 2 data/control input voltage v i C0.5 v cc + 0.3 v 1 notes: 1. absolute maximum ratings are those values beyond which damage to the device may occur if these limits are exceeded for other than a short period of time. see reliability data sheets for specific reliability performance. 2. between absolute maximum ratings and the recommended operating conditions, functional performance is not intended, device reliability is not implied, and damage to the device may occur over an extended period of time. table 4. recommended operating conditions parameter symbol minimum typical maximum unit notes case temperature t c 070?c1 module supply voltage v cc t,r 3.135 3.3 3.465 v 1 data rate fibre channel 1.0625 gb/s 1 2.125 sense output current s d i d 5.0 ma 1 note: 1. recommended operating conditions are those values outside of which functional performance is not intended, device reliability is not implied, and damage to the device may occur over an extended period of time. see reliability data sheet for specific reliability performance. 8 table 7. transmitter and receiver electrical characteristics (v cc t,r = 3.3 v 5%) parameter symbol minimum typical maximum unit notes data input: transmitter differential input v i 400 2400 mv 1 voltage (td +/C) data output: receiver differential output v o 400 650 2000 mv 2 voltage (rd +/C) receive data rise and fall trf 250 ps 3 times (receiver) notes: 1. internally ac coupled and terminated (100 ohm differential). these levels are compatible with cml and lvpecl voltage swings. 2. internally ac coupled with an external 100 ohm differential load termination. 3. 20%-80% rise and fall times measured with a 500 mhz signal utilizing a 1010 data pattern. table 6. transceiver electrical characteristics (v cc t,r = 3.3 v 5%) parameter symbol minimum typical maximum unit notes ac electrical characteristics power supply noise rejection psnr 100 mv 1 (peak-to-peak) dc electrical characteristics module supply current i cc 155 200 ma power dissipation p diss 510 693 mw sense outputs: signal detect [sd] v oh 2.4 v cc r + 0.3 v 2 v ol 0.4 v control inputs: transmitter disable [tx_disable] v ih 2.0 v cc + 0.3 v 3 v il 0.0 0.8 v notes: 1. msa filter is required on host board 10 hz to 2 mhz. 2. lvttl, 1.2 k w internal pull-up resistor to v cc r. 3. 9.0 k w internal pull-down resistor to v ee . 9 table 8. transmitter optical characteristics (v cc t,r = 3.3 v 5%) parameter symbol minimum typical maximum unit notes output optical power (average) p out C10 C6.3 0 dbm 50/125 m m na = 0.2 note 1 p out C10 C6.2 0 dbm 62.5/125 m m na = 0.275 note 1 optical extinction ratio er 9 db optical modulation amplitude oma 196 345 uw fc-pi std (peak-to-peak) 2.125 gb/s note 2 optical modulation amplitude oma 156 380 uw fc-pi std (peak-to-peak) 1.0625 gb/s note 3 center wavelength l c 830 860 nm fc-pi std spectal width C rms s 0.85 nm fc-pi std optical rise /fall time t rise/fall 150 ps 20%C80%, fc-pi std rin 12 (oma), maximum rin C117 db/hz fc-pi std contributed deterministic jitter dj 0.12 ui 4, 5 (transmitter) 2.125 gb/s 56 ps contributed deterministic jitter dj 0.09 ui 4, 6 (transmitter) 1.0625 gb/s 85 ps contributed random jitter rj 0.134 ui 5, 6 (transmitter) 2.125 gb/s 63 ps contributed random jitter rj 0.177 ui 5, 6 (transmitter) 1.0625 gb/s 167 ps p out tx_disable asserted p off C35 dbm notes: 1. max p out is the lesser of 0 dbm or maximum allowable per eye safety standard. 2. an oma of 196 is approximately equal to an average power of C9 dbm assuming an extinction ratio of 9 db. 3. an oma of 156 is approximately equal to an average power of C10 dbm assuming an extinction ratio of 9 db. 4. contributed dj is measured on an oscilloscope in average mode with 50% threshold and k28.5 pattern. 5. contributed rj is calculated for 1x10 -12 ber by multiplying the rms jitter (measured on a single rise or fall edge) from the oscilloscope by 14. per the fc-pi standard (table 13 - mm jitter output, note 1), the actual contributed rj is allowed to increase above its limit if the actual contributed dj decreases below its limits, as long as the component output dj and tj remain within their specified fc-pi maximum limits with the worst case specified component jitter input. 6. in a network link, each components output jitter equals each components input jitter combined with each components contributed jitter. contributed dj adds in a linear fashion and contributed rj adds in a rms fashion. in the fibre channel fc-pi rev 11 specification 6.3.3 mm jitter budget section, there is a table specifying the input and output dj and tj for the transmitter at each data rate. in that table, rj is found from tj C dj, where the tx input jitter is noted as delta t, and the tx output jitter is noted as gamma t. our component contributed jitter is such that, if the maximum specified input jitter is present, and is combined with our maximum contributed jitter, then we meet the specified maximum output jitter limits listed in the fc-pi mm jitter specification table. 10 table 9. receiver optical characteristics (v cc t,r = 3.3 v 5%) parameter symbol minimum typical maximum unit notes optical power pin 0 dbm fc-pi std min optical modulation oma 49 23 m w fc-pi std amplitude (peak-to-peak) note 1 2.125 gb/s min optical modulation oma 31 14 m w fc-pi std amplitude (peak-to-peak) note 2 1.0625 gb/s stressed receiver sensitivity 62.5 m m fiber 2.125 gb/s oma 109 25 m w note 3 1.0625 gb/s oma 67 13 m w 50 m m fiber 2.125 gb/s oma 96 26 m w note 4 1.0625 gb/s oma 55 15 m w return loss 12 db fc-pi std signal detect C de-assert p d C31 C17.5 dbm signal detect C assert p a C17.0 dbm signal detect C hysteresis p a C p d 0.5 2.1 5 db notes: 1. an oma of 49 uw is approximately equal to an average power of -15dbm, and the oma typical of 16 uw is approximately equal to an average power of -20 dbm, assuming an extinction ratio of 9db. sensitivity measurements are made at eye center with ber = 10e -12 . 2. an oma of 31 is approximately equal to an average power of C17 dbm assuming an extinction ratio of 9 db. 3. 2.125 gb/s stressed receiver vertical eye closure penalty (isi) min. is 1.26 db for 50 m m fiber and 2.03 db for 62.5 m m fiber. stressed receiver dcd component min. (at tx) is 40 ps. 4. 1.0625 gb/s stressed receiver vertical eye closure penalty (isi) min. is 0.96 db for 50 m m fiber and 2.18 db for 62.5 m m fiber. stressed receiver dcd component min. (at tx) is 80 ps. 5. these average power values are specified with an extinction ratio of 9db. the signal detect circuitry responds to oma (peak-to-peak) power, not to average power. table 10. transceiver timing characteristics (v cc t,r = 3.3 v 5%) parameter symbol minimum maximum unit notes tx disable assert time t_off 10 m s1 tx disable negate time t_on 1 ms 2 time to initialize t_init 300 ms 3 tx disable to reset t_reset 10 m s4 sd assert time t_loss_on 100 m s5 sd de-assert time t_loss_off 100 m s6 notes: 1. time from rising edge of tx disable to when the optical output falls below 10% of nominal. 2. time from falling edge of tx disable to when the modulated optical output rises above 90% of nominal. 3. from power on or negation of tx fault using tx disable. 4. time tx disable must be held high to reset tx_fault. 5. time from sd state to rx sd assert. 6. time from non-sd state to rx sd de-assert. 11 figure 5. transceiver timing diagrams. tx_fault v cc > 3.15 v t_init tx_disable transmitted signal t_init tx_fault v cc > 3.15 v tx_disable transmitted signal t-init: tx disable de-asserted t-init: tx disable asserted t_off tx_fault tx_disable transmitted signal t-off & t-on: tx disable asserted then negated t_on tx_fault occurance of fault tx_disable transmitted signal t-reset: tx disable asserted then negated, tx signal recovered t_reset t_init* * sfp shall clear tx_fault in < t_init if the failure is transient optical signal rx_sd t-loss-on & t-loss-off t_loss_on t_loss_off occurance of loss 12 figure 6a. module drawing. 48.19 (1.897) 13.59 (0.535) agilent HFBR-5923AL 850 nm laser prod 21cfr(j) class 1 country of origin yyww xxxxxx 15.05 (0.593) uncompressed max. thermocouple test point 6.25 0.05 (0.246 0.002) tx rx 4 x 28.45 (1.120) 13.63 (0.537) 14.68 (0.578) 1.00 (0.039) 4.57 (0.180) 7.11 (0.280) 9.80 (0.39) max. 2.92 (0.115) min. 10.80 (0.425) uncompressed 10.16 (0.400) 3.25 (0.128) 10.16 (0.400) 13.34 (0.525) area for process plug dimensions are in millimeters (inches) 14.20 0.10 (0.559 0.004) 19.59 (0.771) 13.00 0.10 (0.512 0.004) 10 x ? 0.46 0.05 (0.018 0.002) 2 x ? 1.07 (0.042 ) 0 ?.10 +0.000 ?.004 16.01 (0.630) 6789 10 b 5432 1a 13 figure 6b. recommended sff host board and front panel layout. 7.11 (0.280) 4.57 (0.180) 7.59 (0.299) 10.16 (0.400) 15.24 (0.600) see detail a 20x ? 4x ? 2x ? (note 4) 2x ? max. (area for eyelets) 25.75 (1.014) 13.34 (0.525) see detail b 1.78 (0.070) 10.16 0.10 (0.400 0.004) min. pitch 14.22 0.10 (0.560 0.004) a 12 (0.472) ref. max. +0.059 ?.000 notes 1. this page describes the recommended circuit board layout and front panel openings for sff transceivers. 2. the hatched areas are keep-out areas reserved for housing standoffs. no metal traces allowed in keep-out areas. 3. holes for mounting studs must be tied to chassis ground. 4. holes for housing leads must be tied to signal ground. 5. dimensions are in millimeters (inches). 1.40 0.10 (0.055 0.004) (note 5) 0.81 0.10 (0.032 0.004) 6789 10 5432 1 ? 0.00 m a ? 0.00 m a 1.40 0.10 (0.055 0.004) 2.29 (0.090) ? 0.00 m a 9x 1.00 (0.039 ) +1.50 ? 15.24 (0.600) +0.000 ?.030 15.75 (0.620 ) +0 ?.75 minimum pitch �� 6.00 (0.236) detail a (3x) 3.00 (0.118) 3.00 (0.118) �� 1.80 (0.071) 1.00 (0.039) detail b (4x) a a ���� ���� ���� �� top of pcb section a-a � � see note 3 12.16 (0.479) � � 3.56 (0.140) 8.89 (0.350) www.agilent.com/semiconductors for product information and a complete list of distributors, please go to our web site. for technical assistance call: americas/canada: +1 (800) 235-0312 or (408) 654-8675 europe: +49 (0) 6441 92460 china: 10800 650 0017 hong kong: (+65) 6271 2451 india, australia, new zealand: (+65) 6271 2394 japan: (+81 3) 3335-8152(domestic/interna- tional), or 0120-61-1280(domestic only) korea: (+65) 6271 2194 malaysia, singapore: (+65) 6271 2054 taiwan: (+65) 6271 2654 data subject to change. copyright ? 2003 agilent technologies, inc. february 6, 2003 5988-8583en |
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