agilent hfbr-5601/hfct-5611 gigabit interface converters (gbic) for gigabit ethernet data sheet description the hfbr-56xx/hfct-56xx family of interface converters meet the gigabit interface converter specification rev. 5.4, an industry standard. the family provides a uniform form factor for a wide variety of standard connections to transmission media. the converters can be inserted or removed from a host chassis without removing power from the host system. the converters are suitable for interconnections in the gigabit ethernet hubs and switches environment. the design of these converters is also practical for other high performance, point-to- point communication requiring gigabit interconnections. since the converters are hot-pluggable, they allow system configuration changes simply by plugging in a different type of converter. features ? compliant with gigabit interface converter specification rev. 5.4 (1) hfbr-5601 is compliant with proposed specifications for ieee 802.3z/d5.0 gigabit ethernet (1000 base-sx) hfct-5611 is compliant with the ansi 100-sm-lc-l revision 2 10 km link specification performance: hfbr-5601: 500 m with 50/125 m mmf 220 m with 62.5/125 m mmf hfct-5611: 550 m with 50/125 m mmf 550 m with 62.5/125 m mmf 10 km with 9/125 m smf horizontal or vertical installation ael laser class 1 eye safe per iec 60825-1 ael laser class i eye safe per us 21 cfr hot-pluggable applications switch to switch interface high speed i/o for file servers bus extension applications related products 850 nm vcsel, 1 x 9 and sff transceivers for 1000 base sx applications (hfbr-53d5, hfbr-5912e) 1300 nm, 1 x 9 laser t ransceiver for 1000 base-lx applications (hfct-53d5) physical layer ics available for optical i nterface (hdmp-1636a/46a) the mechanical and electrical interfaces of these converters to the host system are identical for all implementations of the converter regardless of external media type. a 20-pin connector is used to connect the converter to the host system. surge currents are eliminated by using pin sequencing at this connector and a slow start circuit. two ground tabs at this connector also make contact before any other pins, discharging possible component- damaging static electricity. in addition, the connector itself performs a two-stage contact sequence. operational signals and power supply ground make contact in stage 1 while power makes contact in stage 2. the hfbr-5601 has been developed with 850 nm short wavelength vcsel technology while the hfct-5611 is based on 1300 nm long wavelength fabry perot laser technology.
2 the hfbr-5601 complies with annex g of the gbic specification revision 5.4. in the 1000 base-sx environment the hfbr-5601 achieves 220 m transmission distance with 62.5 m and 500 m with 50 m multimode fiber respectively. the hfct-5611 complies with annex f of the gbic specification revision 5.4 and reaches 10 km with 9/125 m single mode fiber. both the hfbr-5601 and the hfct-5611 are class 1 eye safe laser devices. serial identification the hfbr-56xx and hfct-5611 family complies with annex d (module definition 4) of the gbic specification revision 5.4, which defines the serial identification protocol. definition 4 specifies a serial definition protocol. for this definition, upon power up, mod_def(1:2) (pins 5 and 6 on the 20-pin connector) appear as nc. pin 4 is ttl ground. when the host system detects this condition, it activates the public domain serial protocol. the protocol uses the 2-wire serial cmos e 2 prom protocol of the atmel at24c01a or similar. the data transfer protocol and the details of the mandatory and vendor specific data structures are defined in annex d of the gbic specification revision 5.4. regulatory compliance see the regulatory compliance table for the targeted typical and measured performance for these transceivers. the overall equipment design will determine the level it is able to be certified to. these transceiver performance targets are offered as a figure of merit to assist the designer in considering their use in equipment designs. electrostatic discharge (esd) there are two design cases in which immunity to esd damage is important. the first case is during handling of the transceiver prior to inserting it into the host system. it is important to use normal esd handling precautions for esd sensitive devices. these precautions include using grounded wrist straps, work benches, and floor mats in esd controlled areas. the second case to consider is static discharges during insertion of the gbic into the host system. there are two guide tabs integrated into the 20-pin connector on the gbic. these guide tabs are connected to circuit ground. when the gbic is inserted into the host system, these tabs will engage before any of the connector pins. the mating connector in the host system must have its tabs connected to circuit ground. this discharges any stray static charges and establishes a reference for the power supplies that are sequenced later. electromagnetic interference (emi) most equipment designs utilizing these high-speed transceivers from agilent will be required to meet the requirements of fcc in the united states, cenelec en55022 (cispr 22) in europe and vcci in japan. immunity equipment utilizing these transceivers will be subject to radio-frequency electromagnetic fields in some environments. these transceivers have good immunity to such fields due to their shielded design. eye safety laser-based gbic transceivers provide class 1 (iec 60825-1) and class i (us 21 cfr[j]) laser eye safety by design. agilent has tested the current transceiver design for compliance with the requirements listed below under normal operating conditions and for compliance under single fault conditions. outline drawing an outline drawing is shown in figure 1. more detailed drawings are shown in gigabit interface converter specification rev. 5.4. note: hfbr-5601 is non-compliant for tx fault timing.
3 gbic serial id memory contents - hfbr-5601 note: blanks in ascii column are numeric values not ascii characters. addr hex ascii addr hex ascii addr hex ascii addr hex ascii 0 1 40 48 h 68 39 9 96 20 1 7 41 46 f 69 38 8 97 20 2 1 42 42 b 70 30 0 98 20 3 0 43 52 r 71 36 6 99 20 4 0 44 2d - 72 32 2 100 20 5 0 45 35 5 73 33 3 101 20 6 1 46 36 6 74 30 0 102 20 7 0 47 30 0 75 33 3 103 20 8 0 48 31 1 76 32 2 104 20 9 0 49 20 77 38 8 105 20 10 0 50 20 78 33 3 106 20 11 1 51 20 79 34 4 107 20 12 0d 52 20 80 33 3 108 20 13 0 53 20 81 37 7 109 20 14 0 54 20 82 33 3 110 20 15 0 55 20 83 30 0 111 20 16 32 56 30 0 84 39 9 112 20 17 16 57 30 0 85 38 8 113 20 18 0 58 30 0 86 30 0 114 20 19 0 59 30 0 87 36 6 115 20 20 41 a 60 0 88 32 2 116 20 21 47 g 61 0 89 33 3 117 20 22 49 i 62 0 90 30 0 118 20 23 4c l 63 74 91 30 0 119 20 24 45 e 64 0 92 0 120 20 25 4e n 65 1a 93 0 121 20 26 54 t 66 0 94 0 122 20 27 20 67 0 95 f3 123 20 28 20 124 20 29 20 125 20 30 20 126 20 31 20 127 20 32 20 33 20 34 20 35 20 36 0 37 00 38 30 39 d3
4 gbic serial id memory contents - hfct-5611 note: blanks in ascii column are numeric values not ascii characters. addr hex ascii addr hex ascii addr hex ascii addr hex ascii 0 1 40 48 h 68 39 9 96 20 1 6 41 46 f 69 38 8 97 20 2 1 42 43 c 70 30 0 98 20 3 0 43 54 t 71 36 6 99 20 4 0 44 2d - 72 32 2 100 20 5 0 45 35 5 73 33 3 101 20 6 2 46 36 6 74 30 0 102 20 7 0 47 31 1 75 33 3 103 20 8 0 48 31 1 76 34 4 104 20 9 0 49 20 77 32 2 105 20 10 0 50 20 78 30 0 106 20 11 1 51 20 79 39 9 107 20 12 0d 52 20 80 34 4 108 20 13 0 53 20 81 32 2 109 20 14 0 54 20 82 39 9 110 20 15 64 55 20 83 30 0 111 20 16 37 56 30 0 84 39 9 112 20 17 37 57 30 0 85 38 8 113 20 18 0 58 30 0 86 30 0 114 20 19 0 59 30 0 87 36 6 115 20 20 41 a 60 0 88 32 2 116 20 21 47 g 61 0 89 33 3 117 20 22 49 i 62 0 90 30 0 118 20 23 4c l 63 3 91 30 0 119 20 24 45 e 64 0 92 0 120 20 25 4e n 65 1a 93 0 121 20 26 54 t 66 0 94 0 122 20 27 20 67 0 95 f3 123 20 28 20 124 20 29 20 125 20 30 20 126 20 31 20 127 20 32 20 33 20 34 20 35 20 36 0 37 00 38 30 39 d3
5 figure 1. outline drawing of hfbr-5601 and hfct-5611.
6 optical power budget and link penalties the worst-case optical power budget (opb) in db for a fiber optic link is determined by the difference 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 establish a working fiber-optic link. the opb is allocated for the fiber-optic cable length and the corresponding link penalties. for proper link perform- ance, all penalties that affect the link performance must be acc- ounted for within the link optical power budget. the gigabit/sec ethernet (gbe) ieee 802.3z standard identifies, and has modeled, the contributions of these opb penalties to establish the link length requirements for 62.5/125 m and 50/125 m multi- mode fiber usage. in addition, single-mode fiber with standard 1300 nm fabry perot lasers have been modeled and specified. refer to ieee 802.3z standard and its supplemental documents that develop the model, empirical results and final specifications. 10 km link support as well as complying with the lx 5 km standard, the hfct-56xx specification provides additional margin allowing for a 10 km gigabit ethernet link on single mode fiber. this is accomplished by limiting the spectral width and center wavelength range of the transmitter while increasing the output optical power and improving sensitivity. all other lx cable plant recommendations should be followed. caution: there are no user serviceable parts nor any maintenance required for the hfbr-56xx and hfct-56xx product family. all adjustments are made at the factory before shipment to our customers. tampering with or modifying the performance of any agilent gbic unit will result in voided product warranty. it may also result in improper operation of the circuitry, and possible overstress of the semiconductor components. device degradation or product failure may result. connection of either the hfbr-5601 or the hfct-5611 to a non-app roved optical source, operating above the recommended absolute maximum conditions, or operating in a manner inconsistent with unit design and function, may result in hazardous radiation exposure and may be considered an act of modifying or manufacturing a laser produ ct. the person(s) performing such an act is required by law to recertify the laser product under the provisions of us 21 cfr (subchapter j). regulatory compliance feature test method targeted performance electrostatic discharge (esd) to the electrical pins mil-std-883c method 3015.4 class 1 (>2000 v) electrostatic discharge (esd) to the duplex sc receptacle variation of iec 801-2 typically withstand at least 15 kv without damage when port is contacted by a human body model probe. electromagnetic interference (emi) fcc class b cenelec en55022 class b (cispr 22a) vcci class 1 margins are dependent on customer board and chassis design. immunity variation of iec 801-3 typically show no measurable effect from a 10 v/m field swept from 27 to 1000 mhz applied to the transceiver without a chassis enclosure laser eye safety us 21 cfr, subchapter j per paragraphs 1002.10 and 1002.12 en 60825-1: 1994+a11 en 60825-2: 1994 en 60950: 1992+a1+a2+a3 ael class i, fda/cdrh hfbr-5601 accession no. 9720151-04 hfct-5611 accession no. 9521220-16 ael class 1, tuv rheinland of north america hfbr-5601 certificate no. r9771018-7 hfct-5611 certificate no. 933/51083 protection class iii component recognition underwriters laboratories and canadian standards association joint component recognition for information technology equipment including electrical business equipment. ul file e173874 (pending)
7 20-pin sca-2 host connector characteristics table 1. sca-2 host connector pin assignment notes: a sequence value of 1 indicates that the signal is in the first group to engage during plugging of a module. a sequence value o f 2 indicates that the signal is the second and last group. the two guide pins integrated on the connector are connected to tgnd. these two guide pins make contact with circuit ground prior to sequence 1 signals. * this pin is tied high via 10 k pull-up resistor. table 2. signal definition table 3. module definition note: all agilent gbic modules comply with module definition 4 of the gbic specification rev 5.4 pin name sequence pin name sequence 1 rx_los 2 11 rgnd 1 2rgnd212-rx_dat1 3rgnd213+rx_dat1 4mod_def(0)214rgnd1 5mod_def(1)215vddr2 6mod_def(2)216vddt2 7 tx_disable* 2 17 tgnd 1 8tgnd218+tx_dat1 9tgnd219-tx_dat1 10 tx_fault 2 20 tgnd 1 pin signal name input/output description 1 rx_los output receiver loss of signal, ttl high, open collector 2 rgnd receiver ground 3 rgnd receiver ground 4 mod_def(0) output ttl low 5 mod_def(1) input scl serial clock signal 6 mod_def(2) input/output sda serial data signal 7 tx_disable input transmit disable 8 tgnd transmitter ground 9 tgnd transmitter ground 10 tx_fault output transmit fault 11 rgnd receiver ground 12 -rx_dat output received data, differential pecl, ac coupled 13 +rx_dat output received data, differential pecl, ac coupled 14 rgnd receiver ground 15 vddr input receiver +5 v supply 16 vddt input transmitter +5 v supply 17 tgnd transmitter ground 18 +tx_dat input transmit data, differential pecl, ac coupled 19 -tx_dat input transmit data, differential pecl, ac coupled 20 tgnd transmitter ground defntn. mod_def(0) pin 4 mod_def(1) pin 5 mod_def(2) pin 6 interpretation by host 4 ttl low scl sda serial module definition protocol
8 short wavelength gbic: hfbr-5601 transmitter section the transmitter section consists of an 850 nm vcsel in an optical subassembly (osa), which mates to the fiber cable. the vcsel osa is driven by a custom, silicon bipolar ic which converts differential logic signals into an analog laser diode drive current. receiver section the receiver includes a gaas pin photodiode mounted together with a custom, silicon bipolar transimpedance preamplifier ic, in an osa. the osa interfaces to a custom silicon bipolar circuit that provides post-amplification and quantization. the post- amplifier includes a signal detect circuit that provides ttl compatible logic-low output in response to the detection of a usable input optical signal. eye safety design the laser driver is designed to be class 1 eye safe (cdrh21 cfr(j), iec 60825-1) under a single fault condition. to be eye safe, only one of two results can occur in the event of a single fault. the transmitter must either maintain normal eye safe operation or the transmitter should be disabled. there are three key elements to the safety circuitry: a monitor diode, a window detector circuit, and direct control of the laser bias. the window detection circuit monitors the average optical power using the monitor diode. if a fault occurs such that the dc regulation circuit cannot maintain the preset bias conditions within 20%, the transmitter will automatically be disabled. once this has occurred, an electrical power reset will allow an attempted turn-on of the transmitter. tx_fault can also be cleared by cycling tx_disable high for a time interval >10 s. 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 affect device reliability. recommended operating conditions transceiver electrical characteristics (t a = 0c to +60c, v cc = 4.75 v to 5.25 v) notes: 1. up to applied v dd t. 2. see figure 1 for measurement point. 3. maximum current is specified at v cc = maximum @ maximum operating temperature and end of life. 4. hot plug above actual steady state current. 5. total t x + r x . parameter symbol min. typ. max. unit notes storage temperature t s -40 +85 c supply voltage v dd t v dd r -0.5 6.0 v data input voltage tx_dat -0.5 v dd tv 1 tra nsmit ter differential input voltage tx_dat 2000 mv p-p relative humidity rh 5 95 % parameter symbol min. typ. max. unit notes ambient operating temperature t a 0+60c case temperature t case +75 c 2 supply voltage v dd t v dd r 4.75 5.0 5.25 v supply current i tx + i rx 200 300 ma 3 parameter symbol min. typ. max. unit notes surge current i surge +30 ma 4 power dissipation p diss 1.00 1.58 w 5
9 hfbr-5601 transmitter electrical characteristics (t a = 0c to +60c, v cc = 4.75 v to 5.25 v receiver electrical characteristics (t a = 0c to +60c, v cc = 4.75 v to 5.25 v) notes: 1. pull-up resistor on host v cc . 2. rising edge of tx_disable to fall of output signal below 10% of nominal. 3. falling edge of tx_disable to rise of output signal above 90% of nominal. 4. from power on or hot plug after v dd t >4.75 v or from negation of tx_disable during reset of tx_fault. 5. from occurrence of fault (output safety violation or v dd t <4.5 v). 6. tx_disable high before tx_disable set low. 7. 20 - 80% values. parameter symbol min. typ. max. unit notes transmitter differential input voltage tx_dat 650 2000 mv p-p tra nsm it fa ul t lo ad tx_fau lt load 4.7 10 k w 1 tx-disable assert time t_off 10 sec 2 tx_disable negate time t-on 1 msec 3 time to initialize, includes reset of tx_fault t_init 300 msec 4 tx_fault from fault to assertion t_fault 7 msec 5 tx_disable time to start reset t_reset 10 sec 6 parameter symbol min. typ. max. unit notes receiver differential output voltage rx_dat 370 2000 mv p-p receiver output rise time t rrx_dat 0.25 0.35 ns 7 receiver output fall time t frx_dat 0.25 0.35 ns 7 receiver loss of light load rx_los load 4.7 10 k w 1 receiver loss of signal output voltage - low rx_los l 0.0 0.5 v receiver loss of signal output voltage - high rx_los h v cc -0.5 v cc +0.3 v receiver loss of signal assert time - logic low to high t a,rx_los 100 s receiver loss of signal deassert time - logic high to low t d,rx_los 100 s
10 hfbr-5601 transmitter optical characteristics (t a = 0c to +60c, v cc = 4.75 v to 5.25 v) receiver optical characteristics (t a = 0c to +60c, v cc = 4.75 v to 5.25 v) notes: 1. 20 - 80 values. 2. modulated with 2 7- 1 prbs pattern. results are for a ber of ie-12. 3. tested in accordance with the conformance testing requirements of ieee802.3z. 4. laser transmitter pulse response characteristics are specified by an eye diagram (figure 2). figure 2. transmitter optical eye diagram mask ������������ � ���������� � � ���������� � � ���������� � � ���������� � � ���������� � � ���������� � � ���������� � � ���������� � � ���������� � � ���������� � � ���������� � ������������ ������� ������� ������� ������� ������� ������� ������� ������� ������� ������� ������� ������� ������� ������� ������� ������� ������� ������� ������� ������� ������� ������� ������� ������� ������� ������� 1.3 1.0 0.8 0.5 0.2 0 -0.2 normalized amplitude normalized time 0 0.22 0.375 0.625 0.78 1.0 parameter symbol min. typ. max. unit notes output optical power 50/125 m, na = 0.20 fiber p o -9.5 -4 dbm avg. output optical power 62.5/125 m, na = 0.275 fiber p o -9.5 -4 dbm avg. optical extinction ratio 9 db center wavelength l c 830 850 860 nm spectral width - rms 0.85 nm rms optical rise/fall time t r /t f 0.26 ns 1, 4 and figure 2 rin 12 -117 db/hz total contributed jitter tj 227 ps p-p coupled power ratio cpr 9 db max. pout tx_disable asserted p off -35 dbm parameter symbol min. typ. max. unit notes input optical power p in -17 -22 0 dbm avg. 2 operating center wavelength l c 770 860 nm return loss 12 db receiver loss of signal - ttl low p rx_los a -23 -17 dbm avg. receiver loss of signal - ttl high p rx_los d -31 -26 dbm avg. stressed receiver sensitivity 62.5 m fiber 50 m fiber -12.5 -13.5 dbm dbm 3 stressed receiver eye opening @tp4 201 ps 3 electrical 3 db upper cutoff frequency 1500 mhz
11 long wavelength gbic: hfct-5611 transmitter section the transmitter section consists of a 1300 nm mqw fabry perot laser in an optical subassembly (osa), which mates to the fiber optic cable. the laser osa is driven by a custom, silicon bipolar ic which converts differential pecl logic signals (ecl referenced to a +5 v supply) into an analog drive current to the laser. the laser driver ic incorporates temperature compensation and feedback from the osa to maintain constant output power and extinction ratio over the operating temperature range. receiver section the receiver includes a pin photodiode mounted together with a custom, silicon bipolar transimpedance preamplifier ic, in an osa. the osa interfaces to a custom silicon bipolar circuit that provides post-amplification and quantization. the post- amplifier includes a signal detect circuit that provides ttl compatible logic-low output in response to the detection of a usable input optical signal. eye safety design the laser driver is designed to be class 1 eye safe (cdrh21 cfr(j), iec 60825-1) under a single fault condition. there are three key elements to the safety circuitry: a monitor diode, a window detector circuit, and direct control of the laser bias. the window detection circuit monitors the average optical power using the photo diode in the laser osa. if a fault occurs such that the dc bias circuit cannot maintain the preset conditions within 20%, tx_fault (pin 10) will be asserted (high). note: under any single fault, the laser optical output power will remain within class 1 eye safe limits. 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 affect device reliability. recommended operating conditions transceiver electrical characteristics (t a = 0c to +60c, v cc = 4.75 v to 5.25 v) notes: 1. see figure 1 for measurement point. 2. maximum current is specified at v cc = maximum @ maximum operating temperature and end of life. 3. hot plug above actual steady state current. 4. total t x + r x . parameter symbol min. typ. max. unit notes storage temperature t s -40 +85 c supply voltage v dd t v dd r -0.5 6.0 v data input voltage tx_dat -0.5 v dd tv tra nsmit ter differential input voltage tx_dat 2000 mv p-p relative humidity rh 5 95 % parameter symbol min. typ. max. unit notes ambient operating temperature t a 0+60c case temperature t case +75 c 1 supply voltage v dd t v dd r 4.75 5.0 5.25 v supply current i tx + i rx 200 300 ma 2 parameter symbol min. typ. max. unit notes surge current i surge +30 ma 3 power dissipation p diss 1.00 1.58 w 4
12 hfct-5611 transmitter electrical characteristics (t a = 0c to +60c, v cc = 4.75 v to 5.25 v) receiver electrical characteristics (t a = 0c to +60c, v cc = 4.75 v to 5.25 v) notes: 1. pull-up resistor on host v cc . 2. rising edge of tx_disable to fall of output signal below 10% of nominal. 3. falling edge of tx_disable to rise of output signal above 90% of nominal. 4. from power on or hot plug after v dd t >4.75 v or from negation of tx_disable during reset of tx_fault. 5. from occurrence of fault (output safety violation or v dd t <4.5 v). 6. tx_disable high before tx_disable set low. 7. 20 - 80% values. parameter symbol min. typ. max. unit notes transmitter differential input voltage tx_dat 650 2000 mv p-p tra nm it fa ult load tx_fau lt load 4.7 10 k w 1 transmit fault output - low tx_fault l 0.0 0.5 v transmit fault output - high tx_fault h v cc -0.5 v cc +0.3 v tx_disable assert time t_off 3 10 sec 2 tx_disable negate time t_on 0.5 1 msec 3 time to initialize, includes reset of tx_fault t_init 30 300 msec 4 tx_fault from fault to assertion t_fault 20 100 sec 5 tx_disable time to start reset t_reset 10 sec 6 parameter symbol min. typ. max. unit notes receiver differential output voltage rx_dat 370 2000 mv p-p receiver output rise time t rrx_dat 0.35 ns 7 receiver output fall time t frx_dat 0.35 ns 7 receiver loss of light load rx_los load 4.7 10 k w 1 receiver loss of signal output voltage - low rx_los l 0.0 0.5 v receiver loss of signal output voltage - high rx_los h v cc -0.5 v cc +0.3 v receiver loss of signal assert time (off to on) t a,rx_los 100 s receiver loss of signal deassert time (on to off) t d,rx_los 100 s
13 hfct-5611 transmitter optical characteristics (t a = 0c to +60c, v cc = 4.75 v to 5.25 v) receiver optical characteristics (t a = 0c to +60c, v cc = 4.75 v to 5.25 v) notes: 1. 20 - 80% values. 2. modulated with 2 7 -1 prbs pattern. results are for a ber of ie-12. 3. tested in accordance with the conformance testing requirements of ieee802.3z. 4. laser transmitter pulse response characteristics are specified by an eye diagram (figure 2). parameter symbol min. typ. max. unit notes output optical power 9/125 m smf 62.5/125 m mmf 50/125 m mmf p o -9.5 -11.5 -11.5 -7 -3 -3 -3 dbm dbm dbm optical extinction ratio 9 db center wavelength l c 1285 1310 1343 nm spectral width - rms 2.8 nm rms optical rise/fall time t r /t f 0.26 ns 1, 4 and figure 2 rin 12 -116 db/hz total contributed jitter tj 227 ps p-p coupled power ratio cpr 9 db max. pout tx_disable asserted p off -35 dbm parameter symbol min. typ. max. unit notes input optical power p in -20 -25 -3 dbm avg. 2 operating center wavelength l c 1270 1355 nm return loss 12 db receiver loss of signal - ttl low p rx_los a -28 -20 dbm avg. receiver loss of signal - ttl high p rx_los d -31 dbm avg. stressed receiver sensitivity -14.4 dbm 3 stressed receiver eye opening @tp4 201 ps 3 electrical 3 db upper cutoff frequency 1500 mhz
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/ international), or 0120-61-1280(domestic only) korea: (+65) 6271 2194 malaysia, singapore: (+65) 6271 2054 taiwan: (+65) 6271 2654 data subject to change. copyright ? 2002 agilent technologies, inc. obsoletes: 5988-0537en july 29, 2002 5988-7407en
|
