HFBR-8 Series HFBR-8 Transmitter HFBR-8 Receiver Megabaud Versatile Link Fiber Optic Transmitter and Receiver for mm POF and µm HCS Data Sheet Description The HFBR-8 Series consists of a fiber-optic transmitter and receiver operating at a 6 nm wavelength (red). The HFBR-8 transmitter is an LED in a low cost plastic housing designed to efficiently couple power into µm diameter HCS and mm diameter POF. The HFBR-8 receiver incorporates a PIN detector and digital output IC compatible with CMOS and TTL logic families. HFBR-8 links operate from DC to MBd at distances up to meters with mm POF and up to meters with µm HCS. No minimum link distances are required when using recommended circuits, simplifying design. Versatile Link components can be interlocked (Nplexed together) to minimize space and to provide dual connections with the duplex connectors. Up to eight packages can be interlocked and inserted into a printed circuit board. POF and HCS are available in pre-connectored lengths or can be easily field-terminated. A single transmitter drive current for POF and HCS allows both fibers to be used with a single design. Features Data transmission at signal rates of dc to MBd Up to meters distances with mm Plastic Optical Fiber (POF) Up to meters distances with µm Hard Clad Silica (HCS ) Wide dynamic range receiver allows operation from zero to maximum link distance with a single transmitter drive current Link distances specified for variations in temperature, power supply, and fiber attenuation DC coupled receiver with CMOS/TTL output for easy designs: no data encoding or digitizing circuitry required Pulse width distortion controlled to limit distortion from low duty cycle or burst mode data High noise immunity Compatible with Avago s Versatile Link family of connectors, for easy termination of fiber Applications Industrial control and factory automation Serial field buses Intra-system links; Board-to-Board, Rack-to-Rack Extension of RS-, RS-8 Elimination of ground loops High voltage isolation Reduces voltage transient susceptibility HCS is a registered trademark of SpecTran Corporation. CAUTION:. It is advised that normal static precautions be taken in handling and assembly of these components to prevent damage and/or degradation which may be induced by ESD.
HFBR-8 Series MBd Data Link Typical Link Performance, T A = + C Parameter Symbol Typ. [] Unit Condition Note Signaling Rate f S Mb/s NRZ Link Distance with Extra Low Loss POF Cable m MBd,, Link Distance with µm HCS Cable 9 m MBd,, Specified Link Performance, T A = - to +8 C, DC to MBd, unless otherwise noted. Parameter Symbol Min. Max. Unit Condition Note Signaling Rate f S DC Mb/s NRZ Link Distance with Extra Low. m + C,, Loss POF Cable. to +7 C. - to +8 C Link Distance with µm. m + C,, HCS Cable. to +7 C. - to +8 C Pulse Width Distortion PWD - + ns 7% Duty Cycle - + ns Arbitrary Duty Cycle Absolute Maximum Ratings Parameter Symbol Min. Max. Unit Note Storage and Operating Temperature T S,O - +8 C Receiver Supply Voltage V CC -. +. V Receiver Average Output Current I O,AVG -6 +6 ma Receiver Output Power Dissipation P OD 8 mw Transmitter Peak Forward Input Current I F,PK 9 ma 6 Transmitter Average Forward Input Current I F,AVG 6 ma Transmitter Reverse Input Voltage V R V Lead Soldering Cycle Temp T SOL +6 C 7 Time sec 7 Recommended Operating Conditions Parameter Symbol Min. Max. Unit Condition Note Ambient Temperature T A - +8 C Power Supply Voltage V CC.7. V < mv p-p Noise Transmitter Peak Forward Current I F,PK 9 ma 6 Transmitter Average Forward Current I F,AV 6 ma Fanout (7 Series TTL) N Notes:. Typical data at + C, V CC = V.. With recommended transmitter and receiver application circuits (6 ma nominal drive current).. POF is HFBR-R/EXXYYY plastic ( mm) optical fiber. Worst case attenuation used (. db/m from - C to +8 C at 66 nm).. HCS is HFBR-H/VXXYYY hard clad silica (/ µm) fiber. Worst case attenuation is used ( db/km from C to +7 C and db/km from - C to +8 C at 6 nm).. BER -9, - PRBS NRZ MBd. 6. For I F,PK > 6 ma, the duty factor must maintain I F,AV 6 ma and pulse with µs. 7..6 mm below seating plane.
HFBR-8 Transmitter The HFBR-8 transmitter incorporates a 6 nm LED in a light gray, nonconductive plastic housing. The high light output power enables the use of both plastic optical fiber (POF) and Hard Clad Silica (HCS) fiber. This transmitter can be operated up to MBd using a simple driver circuit. The HFBR-8 is compatible with all Versatile Link connectors. ANODE CATHODE GROUND GROUND SEE NOTE HFBR-8 Transmitter, Top View 8 GROUND GROUND Electrical and Optical Characteristics: T A = - to +8 C unless otherwise noted. Parameter Symbol Min. Typ. [] Max. Units T A ( C) Conditions Note Peak Output Power P T -6. -.. dbm + I F, dc = 6 ma, mm POF, 6 ma -6.9 +. to +7 Fig. -7. +. - to +8 Peak Output Power P T -.6-9. -. dbm + I F,dc = ma, mm POF, ma -6. -. to +7 Fig. -6.8 -.7 - to +8 Peak Output Power P T -6. -. -8. dbm + I F,dc = 6 ma, µm HCS, 6 ma -7. -8. to +7 Fig. -7. -7. - to +8 Optical Power Tem- P T / T -. %/ C perature Coefficient -. db/ C Peak Emission λ P 6 6 66 nm to +7 Wavelength 6 66 - to +8 Peak Wavelength λ/ T. nm/ C Temperature Coefficient Spectral Width FWHM nm Fig. Forward Voltage V F.8..6 V I F,dc = 6 ma Fig. Forward Voltage Tem- V F / T -.8 mv/ C Fig. perature Coefficient Reverse Input Break- V BR. V I F,dc = - µa down Voltage Diode Capacitance C O 6 pf V F = V, f = MHz Transmitter NA. Numerical Aperture Thermal Resistance, θ jc C/W Junction to Case Ω Optical Rise Time t r ns % to 9%, I F = 6 ma Ω Optical Fall Time t f ns Notes:. Typical data are at C.. Optical power measured at the end of. meters of mm diameter plastic or µm diameter hard clad silica fiber with a large area detector.. Minimum and maximum values for P T over temperature are based on a fixed drive current. The recommended drive circuit has temperature compensation which reduces the variation in P T over temperature; refer to Figures and 6.. Typical value measured from junction to PC board solder joint for horizontal mount package, HFBR-8.. Pins and 8 are for mounting and retaining purposes, but are electrically connected; pins and are electrically isolated. It is recommended that pins,, and 8 all be connected to ground to reduce coupling of electrical noise. 6. Refer to the Plastic Optical Fiber and HCS Fiber Cable and Connectors for Versatile Link Technical Data Sheet for cable connector options for mm plastic and µm HCS optical fiber. Fig.
V F FORWARD VOLTAGE V. - C. C C. 7 C.9.7 8 C. I F,DC TRANSMITTER DRIVE CURRENT ma P T NORMALIZED OUTPUT POWER db - C C - 8 C - - - I F,DC TRANSMITTER DRIVE CURRENT ma Figure. Typical Forward Voltage vs. Drive Current. Figure. Typical Normalized Optical Power vs. Drive Current. NORMALIZED SPECTRAL OUTPUT POWER....8.6.. 6 - C C C 7 C 8 C 6 6 67 69 NORMALIZED OUTPUT POWER....9.8.7 - V CC =. V V CC =. V V CC =.7 V - 6 8 WAVELENGTH (nm) TEMPERATURE C Figure. Typical Normalized Optical Spectra. Figure. Typical Normalized Optical Power vs. Temperature (in Recommended Drive Circuit). PWD ns - - - - V CC =. V V CC =. V V CC =.7 V V CC DATA 7 C R R 6 8 / SN7 C HFBR-8 VALUE R KΩ 8 TOLERANCE % - - - 6 8 TEMPERATURE C R C C 7 Ω. µf. µf % % % Figure. Typical Optical Pulse Width Distortion vs. Temperature and Power Supply Voltage (in Recommended Drive Circuit). Figure 6. Recommended Transmitter Drive Circuit (I F,on = 6 ma Nominal at T A = C). WARNING: WHEN VIEWED UNDER SOME CONDITIONS, THE OPTICAL PORT MAY EXPOSE THE EYE BEYOND THE MAXIMUM PERMISSIBLE EXPO- SURE RECOMMENDED IN ANSI Z6., 99. UNDER MOST VIEWING CONDITIONS THERE IS NO EYE HAZARD.
HFBR-8 Receiver The HFBR-8 receiver consists of a silicon PIN photodiode and digitizing IC to produce a logic compatible output. The IC includes a unique circuit to correct the pulse width distortion of the first bit after a long idle period. This enables operation from DC to MBd with low PWD for arbitrary data patterns. The receiver output is a push-pull stage compatible with TTL and CMOS logic. The receiver housing is a dark, conductive plastic, compatible with all Versatile Link connectors. GROUND IC GROUND 8 SEE NOTES,7 HFBR-8 Receiver, Top View NO CONNECT V CC GROUND V O Electrical and Optical Characteristics: T A = - to +8 C,.7 V < V <. V, unless otherwise noted. CC Parameter Symbol Min. Typ.[] Max. Unit T A ( C) Condition Note Fig. Peak POF Sensitivity: P RL,min -. -. dbm + mm POF,,6, Minimum Input for -. to +7 PWD < ns Logic -9. - to +8 Peak POF Overdrive P RL,max +. +. dbm + mm POF,,,,, Limit:Maximum +. to +7 PWD < ns 6 Input for Logic -. - to +8 Peak POF Off State P RH,max - dbm mm POF,6, Limit: Maximum 8 Input for Logic Peak HCS P RL,min -. -. dbm + µm HCS,,6 Sensitivity: Minimum -. to +7 PWD < ns Input for Logic -. - to +8 Peak HCS Overdrive P RL,max -. +. dbm + µm HCS,,, Limit: Maximum -. to +7 PWD < ns 6 Input for Logic -. - to +8 Peak HCS Off State P RH,max - dbm µm HCS,6, Limit: Maximum 8 Input for Logic Supply Current I CC 7 ma V O = Open High Level Output V OH..7 V Voltage I O = - µa Low Level Output V OL.. V Voltage I O = +.6 ma Output Rise Time t r ns C L = pf 6 Output Fall Time t f ns C L = pf 6 Thermal Resistance, θ jc C/W Junction to Case Electric Field E MAX 8 V/m Near Field, Immunity Electrical Field Source Power Supply PSNI.. V pp Sine Wave 6 Noise Immunity DC - MHz Notes:. Typical data are at + C, V CC =. V.. Input power levels are for peak (not average) optical input levels. For % duty cycle data, peak optical power is twice the average optical power.. Receiver overdrive (P RL,max ) is specified as the limit where PWD will not exceed ns. The receiver will be in the correct state (logic ) for optical powers above P RL,max. However, it may not meet a % symbol period PWD if the overdrive limit is exceeded. Refer to Figure for PWD performance at high received optical powers.. Typical value measured from junction to PC board solder joint for horizontal mount package, HFBR-8.. Pins and 8 are electrically connected to the conductive housing and are also used for mounting and retaining purposes. It is required that pins and 8 be connected to ground to maintain conductive housing shield effectiveness. 6. In recommended receiver circuit, with an optical signal from the recommended transmitter circuit. 7. Pin is electrically isolated internally. Pin may be externally connected to pin for board layout compatibility with HFBR-X, HFBR-X and HFBR-X. Otherwise it is recommended pin be grounded as in Figure. 8. BER E-9, includes a.8 db margin below the receiver switching threshold level (signal to noise ratio = ).
6 V CC =. V RECEIVED POWER dbm V CC =.7 V V CC =. V RECEIVED PWD ns - - - - 6 8 - - -8 - - -6 - TEMPERATURE C P RL RECEIVER OPTICAL INPUT POWER dbm Figure. Typical POF Receiver Overdrive, P RL,max, at MBd, vs. Temperature and Power Supply Voltage. Figure. Typical POF Receiver Pulse Width Distortion vs. Optical Power at MBd. 6 - - PWD ns PWD ns - -6-7 9.7.8.9...... -8.7.8.9...... V CC VOLTS V CC VOLTS Figure. Typical POF Receiver Pulse Width Distortion vs. Power Supply Voltage at High Optical Power ( dbm,pk, MBd). Figure. Typical POF Receiver Pulse Width Distortion vs. Power Supply Voltage at Low Optical Power, (- dbm,pk, MBd). HFBR-8 IC 8 C R V CC DATA R C VALUE.7 Ω. µf TOLERANCE % % Figure. Recommended Receiver Application Circuit. 6
8 GROUND V CC PIN PHOTODIODE AMPLIFIER REFERENCE VOLTAGE THRESHOLD GENERATOR FIRST BIT BURST PWD CORRECTION COM- PARATOR V O, DATA GROUND GROUND Figure 6. HFBR-8 Receiver Block Diagram. Versatile Link Mechanical Dimensions Versatile Link Printed Circuit Board Layout Dimensions PIN NO. INDICATOR. (.8).6 (.) 8.9 (.7) 6. (.) 7.6 (.). (.). (.). (.6). (.) 7.6 (.) 8. (.) DIA. 7.6 (.) 7.6 (.).8(.) MAX..6 (.) MIN.. (.).7 (.). (.) TOP VIEW.8 (.7) MIN..6 (.) DIA.. (.8).7 (.68) NOTE: ALL DIMENSIONS IN MM (INCHES). ALL DIMENSIONS ±. mm UNLESS OTHERWISE SPECIFIED. 8 ELECTRICAL PIN FUNCTIONS PIN NO. TRANSMITTER HFBR-8 ANODE CATHODE GROUND* GROUND* GROUND** GROUND** RECEIVER HFBR-8 SIGNAL, V O GROUND V CC (+ V) GROUND* GROUND** GROUND** * NO INTERNAL CONNECTION, GROUND CONNECTION RECOMMENDED. ** PINS AND 8 CONNECTED INTERNALLY TO EACH OTHER.
For product information and a complete list of distributors, please go to our website: 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 7 Avago Technologies Limited. All rights reserved. Obsoletes 988-67EN AV-99EN - December 7, 7 8