Features Links with 9/125 single mode fiber (SMF) links 62.5/125 multi
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Agilent HFCT-59L1ATL Single Mode Laser Transceivers Gigabit Ethernet Fibre Channel Applications (1.0625/1.25 Gb/s)
Features Links with 9/125 single mode fiber (SMF) links 62.5/125 multimode fiber (MMF) Compliant with ANSI Fiber Channel Physical Interfaces (FCPI) Compliant IEEE 802.3, 2000 Edition Compliant Small Form Factor specifications package style with receptacle Single +3.3 power supply Case operating temperature range: HFCT-59L1ATL-10°C +85°C Manufactured ISO9002 certified facility Fully Class CDRH/IEC compliant Wave solder aqueous wash process compatible Applications Mass storage system Computer system High speed peripheral interface High speed switching systems Host adaptor
Description HFCT-59L1ATL transceiver high performance, cost effective module serial optical data communications applications operating 1.0625 Gb/s 1.25 Gb/s. This module designed single mode fiber operates nominal wavelength 1310 incorporates high performance, reliable, long wavelength optical devices proven circuit technology give long life consistent service. transmitter section incorporates 1310 Fabry Perot (FP) laser. transmitter full CDRH Class safety. receiver section uses MOVPE grown planar SEDET photo detector dark current excellent responsivity.
transceiver supplied industry standard style package with fiber connector interface footprint compatible with Multi Source Agreement (MSA).
Functional Description Receiver Section Design receiver section HFCT-59L1ATL contains InGaAs/InP photo detector pre-amplifier mounted optical subassembly. This optical subassembly coupled post-amplifier/decision circuit circuit board. design optical assembly such that provides better than Optical Return Loss (ORL). post-amplifier coupled pre-amplifier illustrated Figure coupling capacitors capable passing Gigabit Ethernet test pattern 1.0625 Gb/s without significant distortion performance penalty. lower signal rate, code which significantly more frequency content used, sensitivity, jitter pulse distortion could degraded. Noise Immunity receiver includes internal circuit components filter power supply noise. However under some conditions power supply noise, external power supply filtering necessary (see Application Section). Signal Detect Circuit signal detect circuit works sensing peak level received signal comparing this level reference. output voltage TTL.
Figure also shows filter function which limits bandwidth pre-amplifier output signal. filter designed bandlimit preamplifier output noise thus improve receiver sensitivity. These components will reduce sensitivity receiver signal rate increased above 1.25 Gb/s.
TRANSIMPEDANCE PREAMPLIFIER
FILTER AMPLIFIER
DATA PECL OUTPUT BUFFER
DATA
SIGNAL DETECT CIRCUIT
OUTPUT BUFFER
Figure Receiver Block Diagram
Functional Description Transmitter Section Design schematic diagram transmitter shown Figure HFCT-59L1ATL incorporates laser been designed compliant with safety requirements under single fault condition CDRH under normal operating conditions. optical output controlled custom that detects laser output monitor photodiode. This provides both current drive laser ensure correct modulation, diagram extinction ratio over temperature, supply voltage operating life.
LASER
PHOTODIODE (rear facet monitor)
DATA DATA PECL INPUT
LASER MODULATOR
LASER BIAS DRIVER
LASER BIAS CONTROL
Figure Simplified Transmitter Schematic
Package overall package concept device consists following basic elements; optical subassemblies, electrical subassemblies housing illustrated block diagram Figure package outline drawing shown Figures details this package outline compliant with multisource definition DIP. electrical subassemblies consist high volume multilayer printed circuit boards which various surface-mounted passive circuit elements attached.
receiver electrical subassembly includes internal shield electrical optical subassembly ensure high immunity external fields. optical subassemblies each attached their respective transmit receive electrical subassemblies. These units then placed within outer housing transceiver. outer housing transceiver molded with nonconductive plastic provide mechanical strength. housing then encased with metal protective shield. case signal ground recommend soldering four ground tabs host card signal ground.
SUPPLY
Each electrical subassembly carries signal pins that exit from bottom transceiver. solder posts fastened into molding device. This design provides mechanical strength required withstand additional stresses transceiver resulting from insertion force fiber cable mating. Although solder posts connected electrically transceiver, recommended that they connected chassis ground.
DATA QUANTIZER DATA SIGNAL DETECT GROUND DATA DATA DISABLE LASER BIAS MONITORING LASER DRIVER CONTROL CIRCUIT LASER DIODE OUTPUT POWER MONITORING GROUND RECEPTACLE PHOTODIODE PREAMPLIFIER SUBASSEMBLY
LASER OPTICAL SUBASSEMBLY
SUPPLY
CASE
NOSE CLIP PROVIDES CONNECTION CHASSIS GROUND IMPROVED PERFORMANCE
Figure Block Diagram
15.0 (0.591 0.008)
13.59 0.535 -0.008
VIEW
13.59 (0.535)
6.25 (0.246)
48.2 (1.898)
10.8 (0.425 0.008)(0.378 ±0.008) 4.06 (0.16) (0.039)
(0.386) 3.81 (0.15) (0.02) 1.78 (0.07) 0.25 (0.01)
10.16 (0.4)
1.07 (0.042) 19.5 ±0.3 (0.768 ±0.012)
(0.039) BACK VIEW
FRONT VIEW
SIDE VIEW
0.25 (PIN THICKNESS) (0.01) NOTE: PINS CHAMFERED
BOTTOM VIEW
TCASE REFERENCE POINT
DIMENSIONS MILLIMETERS (INCHES) DIMENSIONS SHOWN NOMINAL. DIMENSIONS MEET MAXIMUM PACKAGE OUTLINE DRAWING MSA.
Figure HFCT-59L1ATL Package Outline Drawing
Connection Diagram
Mounting Studs/ Solder Posts
Package Grounding Tabs
View
RECEIVER SIGNAL GROUND RECEIVER POWER SUPPLY SIGNAL DETECT RECEIVER DATA RECEIVER DATA
TRANSMITTER DATA TRANSMITTER DATA TRANSMITTER DISABLE TRANSMITTER SIGNAL GROUND TRANSMITTER POWER SUPPLY
Figure Diagram (Top View)
Descriptions: Receiver Signal Ground Directly connect this receiver ground plane. Receiver Power Supply Provide +3.3 recommended receiver power supply filter circuit. Locate power supply filter circuit close possible pin. Note: filter circuit should cause drop below minimum specification. Signal Detect Normal optical input levels receiver result logic output. optical input levels receiver result logic output. This Signal Detect output used drive LVTTL input upstream circuit, such Signal Detect input Loss Signal-bar. Receiver Data RD-: Output internally biased coupled. Receiver Data RD+: Output internally biased coupled. Transmitter Power Supply Provide +3.3 recommended transmitter power supply filter circuit. Locate power supply filter circuit close possible pin. Transmitter Signal Ground Directly connect this transmitter signal ground plane. Transmitter Disable TDIS: Optional feature, connect this +3.3 logic high disable module. enable module connect logic "0". Transmitter Data TD+: Input internally terminated coupled. Transmitter Data TD-: Input internally terminated coupled. Mounting Studs/Solder Posts mounting studs provided transceiver mechanical attachment circuit board. recommended that holes circuit board connected chassis ground. Package Grounding Tabs Connect four package grounding tabs signal ground.
Application Information Applications Engineering Group Agilent available assist with technical understanding design tradeoffs associated with these transceivers. contact them through your Agilent sales representative. following information provided answer some most common questions about parts. Optical Power Budget Link Penalties worst-case Optical Power Budget (OPB) fiberoptic link determined difference between minimum transmitter output optical power (dBm avg) lowest receiver sensitivity (dBm avg). This provides necessary optical signal range establish working fiber-optic
TDIS (LVTTL)
link. allocated fiber-optic cable length corresponding link penalties. proper link performance, penalties that affect link performance must accounted within link optical power budget. Gigabit Ethernet IEEE 802.3 standard identifies, modeled, contributions these penalties establish link length requirements 62.5/125 50/125 multimode fiber usage. addition, single mode fiber with standard 1310 Fabry-Perot lasers have been modeled specified. Refer IEEE 802.3 standard supplemental documents that develop model, empirical results specifications.
Refer Section 38.11.4 specification offset-launch mode-conditioning patch cord required operation HFCT-59L1ATL. Link Support well complying with 1000Base-LX standard, HFCT-59L1ATL specification provides additional margin allowing link single mode fiber. This accomplished limiting spectral width center wavelength range transmitter while increasing output optical power improving sensitivity. other 1000Base-LX cable plant recommendations should followed.
(+3.3
TDNOTE
TDIS
(+3.3
(+3.3
NOTE
LVTTL
TD+, INPUTS INTERNALLY TERMINATED COUPLED. RD+, OUTPUTS INTERNALLY BIASED COUPLED. Note CIRCUIT ASSUMES OPEN EMITTER OUTPUT. Note CIRCUIT ASSUMES HIGH IMPENDANCE INTERNAL BIAS
Note:
Figure Recommended Interface Circuit
Electrical Mechanical Interface Recommended Circuit Figure shows recommended interface deploying Agilent transceivers +3.3 system. Data Line Interconnections Agilent's HFCT-59L1ATL fiberoptic transceivers designed couple +3.3 PECL signals. transmitter driver circuit regulates output optical power. regulated light output will maintain constant output optical power provided data pattern balanced duty cycle. data duty cycle long, continuous state times (low high data duty cycle), then output optical power will gradually change average output optical power level preset value.
HFCT-59L1ATL transmit disable function which single-ended +3.3 input which dc-coupled receiver section internally ac-coupled between preamplifier post-amplifier stages. Data Data-bar outputs post-amplifier internally biased ac-coupled their respective output pins (Pins Signal Detect single-ended, +3.3 compatible output signal that dc-coupled module. Signal Detect should ac-coupled externally follow-on circuits because infrequent state changes.
Caution should taken account proper interconnection between supporting Physical Layer integrated circuits these transceivers. Figure illustrates recommended interface circuit interconnecting +3.3 PECL fiber-optic transceiver.
2.29 MAX. ±0.1 (0.09) (0.055 ±0.004)
17.8 (0.700) ±0.1 7.11 (0.055 ±0.004) (0.28)
3.56 (0.14)
±0.1 (0.055 ±0.004) 13.34 (0.525) 10.16 (0.4)
7.59 (0.299)
9.59 (0.378)
(0.079)
(0.118)
(0.118) (0.236) 4.57 (0.18)
1.78 (0.07)
2.29 (0.079) (0.09) 0.81 ±0.1 (0.032 ±0.004)
3.08 (0.121)
DIMENSIONS MILLIMETERS (INCHES) NOTES: THIS FIGURE DESCRIBES RECOMMENDED CIRCUIT BOARD LAYOUT TRANSCEIVER. HATCHED AREAS KEEP-OUT AREAS RESERVED HOUSING STANDOFFS. METAL TRACES GROUND CONNECTION KEEP-OUT AREAS. TRANSCEIVER MODULE REQUIRES HOLES PINS, SOLDER POSTS PACKAGE GROUNDING TABS). PACKAGE GROUNDING TABS SHOULD CONNECTED SIGNAL GROUND. MOUNTING STUDS SHOULD SOLDERED CHASSIS GROUND MECHANICAL INTEGRITY ENSURE FOOTPRINT COMPATIBILITY WITH OTHER TRANSCEIVERS. HOLES HOUSING LEADS MUST TIED SIGNAL GROUND.
Figure Recommended Board Layout Hole Pattern
Power Supply Filtering Ground Planes important exercise care circuit board layout achieve optimum performance from these transceivers. Figure shows power supply circuit which complies with Small Form Factor Multisource Agreement. further recommended that continuous ground plane provided circuit board directly under transceiver provide inductance ground signal return current. This recommendation keeping with good high frequency board layout practices. Package footprint front panel considerations Agilent transceivers comply with circuit board "Common Transceiver Footprint" hole pattern defined current multisource agreement which defined package style. This drawing reproduced Figure with addition ANSI Y14.5M compliant dimensioning used guide mechanical layout your circuit board. Figure shows front panel dimensions associated with such layout. Safety Circuit optical transmitter device eye-safe event single fault failure, transmit-ter must either maintain eye-safe operation disabled. HFCT-59L1ATL intrinsically safe does require shut down circuitry. Signal Detect Signal Detect circuit provides de-asserted output signal when optical link broken when remote transmitter OFF). Signal Detect threshold transition from high
15.24 (0.6)
10.16 (0.4 0.004)
DETAIL
000000000 000000000 000000000 000000000 000000000
15.24 (0.6)
(0.039)
00000000000000000000000000000 00000000000000000000000000000
14.22 ±0.1 (0.56 ±0.004)
SOLDER POSTS
0000000000 00000000000000000000000000000 0000000000 00000000000000000000000000000
15.75 MAX. 15.0 MIN. (0.62 MAX. 0.59 MIN.) SECTION
DIMENSIONS MILLIMETERS (INCHES) FIGURE DESCRIBES RECOMMENDED FRONT PANEL OPENING TRANSCEIVER. TRANSCEIVER PLACED 15.24 (0.6) MIN. SPACING.
Figure Recommended Panel Mounting
state between minimum receiver input optical power avg. input optical power indicating definite optical fault (e.g. unplugged connector receiver transmitter, broken fiber, failed far-end transmitter data source). Signal Detect does detect receiver data error error-rate. Data errors determined signal processing offered upstream ICs. Electromagnetic Interference (EMI) circuit board designer's foremost concerns control electromagnetic emissions from electronic equipment. Success controlling generated Electromagnetic Interference (EMI) enables designer pass governmental agency's regulatory standard more importantly, reduces possibility interference neighboring equipment. Agilent designed HFCT-59L1ATL provide good performance. performance chassis
dependent physical design features which help improve suppression. Agilent encourages using standard suppression practices avoiding poorly EMI-sealed enclosures. Agilent's transceivers (HFCT59L1ATL) have nose shields which provide convenient chassis connection nose transceiver. This nose shield improves system performance effectively closing aperture. Localized shielding also improved tying four metal housing package grounding tabs signal ground PCB. Though obvious inspection, nose shield metal housing electrically separated customers wish directly chassis signal grounds together. Figure shows recommended positioning transceivers with respect faceplate.
Package Handling Instructions Flammability HFCT-59L1ATL transceiver housing consists high strength, heat resistant flame retardant plastic metal packaging. Recommended Solder Wash Process HFCT-59L1ATL compatible with industrystandard wave solder processes. Process plug This transceiver supplied with process plug protection optical port within connector receptacle. This process plug prevents contamination during wave solder aqueous rinse well during handling, shipping storage. made hightemperature, molded sealing material that withstand +85°C rinse pressure square inch.
Recommended Solder fluxes Solder fluxes used with HFCT-59L1ATL should water-soluble, organic fluxes. Recommended solder fluxes include Lonco 3355-11 from London Chemical West, Inc. Burbank, Flux from Alpha-Metals Jersey City,
Recommended Cleaning/Degreasing Chemicals Alcohols: methyl, isopropyl, isobutyl. Aliphatics: hexane, heptane Other: naphtha. partially halogenated hydrocarbons such 1,1.1 trichloroethane, ketones such MEK, acetone, chloroform, ethyl acetate, methylene dichloride, phenol, methylene chloride, N-methylpyrolldone. Also, Agilent does recommend cleaners that halogenated hydrocarbons because their potential environmental harm. Cleaning Recommendations event contamination optical ports, recommended cleaning process forced nitrogen. contamination thought have remained, optical ports cleaned using international Cletop stick type (diam. 1.25mm) HFE7100 cleaning fluid.
Regulatory Compliance Regulatory Compliance transceiver performance shown Table overall equipment design will determine certification level. transceiver performance offered figure merit assist designer considering their equipment designs. Electrostatic Discharge (ESD) device been tested comply with MIL-STD-883 (Method 3015). important normal handling precautions sensitive devices. These precautions include using grounded wrist straps, work benches, floor mats controlled areas.
Electromagnetic Interference (EMI) Most equipment designs utilizing these high-speed transceivers from Agilent will required meet regulations United States, CENELEC EN55022 (CISPR Europe VCCI Japan. Refer section (page more details. Immunity Transceivers will subject radio-frequency electromagnetic fields following 61000-4-3 test method.
Safety These laser-based transceivers classified Class (U.S. CFR(J) Class IEC60825-1 (+A11). They safe when used within data sheet limits CDRH. They also safe under normal operating conditions under reasonably foreseeable single fault conditions IEC60825-1. Agilent tested transceiver design compliance with requirements listed below. These tests were conducted under normal operating conditions under single fault conditions where applicable. Rheinland granted certification these transceivers laser safety IEC60825-2 applications. Their performance enables transceivers used without concern safety transmitter VCC.
Table Regulatory Compliance Targeted Specification
Feature Test Method Performance
Class kV). Tested contact discharge. Margins dependent customer board chassis designs.
Electrostatic Discharge (ESD) MIL-STD-883 Electrical Pins Method 3015 Electrostatic Discharge (ESD) Variation 61000-4-2 Receptacle Electromagnetic Interference (EMI) Class CENELEC EN55022 Class (CISPR 22A) Immunity VCCI Class Variation 61000-4-3
Typically show measurable effect from field swept from 1000 applied transceiver without chassis enclosure.
Laser Safety Equipment CDRH Type Testing 21-CFR 1040 Class
Accession Number: HFCT-59L1ATL 9521220-65
License Number: 60825-1 Amendment 2001 Component Recognition Underwriters Laboratories Canadian Standards Association Joint Component Recognition Information Technology Equipment Including Electrical Business Equipment.
HFCT-59L1ATL 933/510219/01
File Number: E173874
CAUTION: There user serviceable parts maintenance required HFCT-59L1ATL. adjustments made factory before shipment customers. Tampering with modifying performance parts will result voided product warranty. also result improper operation circuitry, possible overstress laser source. Device degradation product failure result. Connection devices non-approved optical source, operating above recommended absolute maximum conditions operating HFCT-59L1ATL manner inconsistent with design function result hazardous radiation exposure considered modifying manufacturing laser product. person(s) performing such required re-certify re-identify laser product under provisions U.S. (Subchapter
Absolute Maximum Ratings
Stresses excess absolute maximum ratings cause catastrophic damage device. Limits apply each parameter isolation, other parameters having values within recommended operating conditions. should assumed that limiting values more than parameter applied product same time. Exposure absolute maximum ratings extended periods adversely affect device reliability.
Parameter
Storage Temperature (non-operating) Relative Humidity Supply Voltage Input Voltage
Symbol
Unit
Notes
-0.5 -0.5
Recommended Operating Conditions
Parameter
Case Operating Temperature: Supply Voltage Power Supply Noise Rejection Data Output Load Transmit Disable Input Voltage Transmit Disable Input Voltage High Transmit Disable Assert Time Transmit Disable Deassert Time
Symbol
PSNR TDIS TDIS TASSERT TDEASSERT
Unit
mVP-P
Notes
Process Compatibility
Parameter
Wave Soldering Aqueous Wash
Symbol
TSOLD/tSOLD
+260/10
Unit
°C/sec.
Notes
Notes: transceiver class safe Tested with sinusoidal signal frequency range from supply with recommended power supply filter place. Typically less than change sensitivity experienced. Time delay from Transmit Disable Assertion laser shutdown. Time delay from Transmit Disable Deassertion laser startup. Aqueous wash pressure <110 psi.
Transmitter Electrical Characteristics HFCT-59L1ATL -10°C +85°C,
Parameter
Supply Current Transmitter Power Dissipation Data Input Voltage Swing (single-ended) Transmitter Differential Data Input Current Transmitter Differential Data Input Current High -350
Symbol
ICCT PDIST
Unit
Notes
Receiver Electrical Characteristics HFCT-59L1ATL -10°C +85°C,
Parameter
Supply Current Receiver Power Dissipation Data Output Voltage Swing (single-ended) Data Output Rise Time Data Output Fall Time Signal Detect Output Voltage Signal Detect Output Voltage High Signal Detect Assert Time (OFF Signal Detect Deassert Time OFF)
Symbol
ICCRX PDISS ASMAX ANSMAX
0.40 0.40
Unit
Notes
Notes: These outputs compatible with PECL inputs. These 20-80% values. LVTTL compatible.
Transmitter Optical Characteristics HFCT-59L1ATL -10°C +85°C, Parameter Symbol
Output Optical Power 62.5 Optical Extinction Ratio Optical Modulation Amplitude (Peak Peak) Center Wavelength Spectral Width Optical Rise/Fall Time Random Intensity Noise Contributed Deterministic Jitter Contributed Total Jitter Coupled Power Ratio 52.5 Coupled Power Ratio TRISE/FALL RIN12 POUT POUT POUT -9.5 -11.5 -11.5 0.174 1278
Unit
Notes
Figs 9a,b 1.0625Gb/s
1343
0.26 1.25Gb/s 0.32 1.0625Gb/s -120 dB/Hz 84.7 0.284 28<CPR<40 12<CPR<20
Notes: maximum Optical Output Power complies with FC-PI specification, class laser safe. 0.174mW approximately equal average power -9.5dBm assuming Extinction Ratio order meet link power budget transmitter trade OMA, spectral width center wavelength shown Figure These unfiltered 20-80% values. diagram (Figures specifies laser transmitter pulse response characteristics. characteristics include rise time, fall time, pulse undershoot, ringing, which controlled prevent excessive degradation receiver sensitivity. output optical waveform 1.0625 Gb/s complies with requirements mask discussed section 6.2.1 FC-PI output optical waveform 1.25 Gb/s complies with requirements mask discussed section 38.6.5 38-2 IEEE 802.3.
NORMALIZED AMPLITUDE
spectral width (nm)
0000000000000 00000000 00000000 00000000 00000000 0000000000000 00000000 00000000 0000000000000 00000000 00000000 0000000000000 00000000 00000000 0000000000000 00000000 00000000 0000000000000 00000000 00000000 0000000000000 00000000 00000000 0000000000000 00000000 0000000000000 00000000 0000000000000 00000000 00000000 00000000 0000000000000 00000000 00000000 00000000 0000000000000 00000000 0000000000000 00000000 00000000 0000000000000 00000000
Minimum Launched Power -9.5
-0.2
0.15
0.35
0.65
0.85
1270
Figure FC1063 Transmitter mask diagram
NORMALIZED AMPLITUDE NORMALIZED TIME (UNIT INTERVAL) 0.625 0.22 0.375 0.78 1.30 NORMALIZED AMPLITUDE
NORMALIZED TIME
1280
1290
1300
1310
1320
1330
1340
1350
1360
Wavelength (nm)
Figure Maximum spectral width tradeoff curve derived from Gigabit Ethernet Link model
1.00 0.80 0.50
37.5 62.5 NORMALIZED TIME UNIT INTERVAL)
0.20 -0.20
Figure Gigabit Ethernet Transmitter mask diagram
Receiver Optical Characteristics HFCT-59L1ATL -10°C +85°C,
Parameter
Receiver Overload Receiver Sensitivity Optical Modulation Amplitude Receiver Electrical Upper Cutoff Frequency Receiver Electrical 10dB Upper Cutoff Frequency Stressed Receiver Sensitivity Stressed Receiver Opening Operating Center Wavelength Return Loss Signal Detect Asserted Signal Detect Deasserted Signal Detect Hysteresis 1270 1570
Symbol
Unit
Notes
0.015 1500 3000 -14.4
1.25 Gb/s
Notes: receiver sensitivity measured using worst case extinction ratio penalty while sampling center eye. 27-1 PRBS receiver guaranteed provide output data with better than equal 1E-12 BER. Typical measured 1.25 Gb/s. 0.015mW approximately equal average power -20dBm assuming Extinction Ratio stressed receiver sensitivity measured using conformance test signal conditioned applying deterministic jitter inter symbol interference. stressed received jitter measured using conformance test signal conditioned applying deterministic jitter inter symbol interference. Average optical power greater than specified stressed receiver sensitivity.
Design Support Materials Agilent created reference design with HDMP-1687 order demonstrate full functionality interoperability. Such design information results made available designer technical aid. Please contact your Agilent representative further information required.
Ordering Information 1310 Laser (Case Temperature range -10°C +85°C) HFCT-59L1ATL
Related Products Other single mode Gigabit Ethernet transceivers this product family are: HFCT-5911ATL2x5 HFCT-5914ATL2x10
Class Laser Product: This product conforms
applicable requirements 1040 date manufacture Date Manufacture: Agilent Technologies Inc., Yishun Singapore
Handling Precautions HFCT-59L1ATL damaged current surges overvoltage. Power supply transient precautions should taken. Normal handling precautions electrostatic sensitive devices should taken.
www.agilent.com/ semiconductors
product information complete list distributors, please site. technical assistance call: Americas/Canada: (800) 235-0312 (408) 654-8675 Europe: 6441 92460 China: 10800 0017 Hong Kong: (+65) 6271 2451 India, Australia, Zealand: (+65) 6271 2394 Japan: (+81 0120-61-1280(Domestic Only) Korea: (+65) 6271 2194 Malaysia, Singapore: (+65) 6271 2054 Taiwan: (+65) 6271 2654 Data subject change. Copyright 2002 Agilent Technologies, Inc. Obsoletes: 5988-7981EN October 2002 5988-8137EN
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