AFBR-16xxZ and AFBR-26x4Z/25x9Z DC-50MBd Versatile Link Fiber Optic Transmitter and Receiver for 1 mm POF and 200 m PCS Data Sheet Description Features The AFBR-16xxZ transmitter utilizes a 650 nm LED source with integrated optics and driver IC for efficient coupling into 1 mm Polymer Optical Fiber (POF). The AFBR26x4Z/25x9Z receiver consists of an IC with an integrated photodiode to produce a logic compatible output. The transmitter input and receiver output are compatible with TTL logic families. The pair operates any type of signal from DC up to 50 MBd at distances up to 50 m with 1 mm POF, up to 200 m at 10 MBd and 120 m at 50 MBd with 200 m Plastic-Clad Silica (PCS), respectively. RoHS-compliant The transmitter is a 3-pin and the receiver is a 4-pin device, packed in Versatile Link housing. Versatile Link components can be interlocked (N-plexed together) to minimize space and to provide dual connections with the duplex connectors. Various simplex and duplex connectors, as well as POF cables are available for Versatile Link components. For details, contact Avago Technologies or visit our company website at www.avagotech.com AFBR-xxx4Z are delivering non-inverted output signals while AFBR-xxx9Z deliver inverted output signals. Z = Extended Temperature Range, RoHS Compliant 4 = 50 MBd Non-Inverted 9 = 50 MBd Inverted Available options AFBR-x624Z AFBR-x634Z AFBR-x644Z Up to 50 m distance with 1 mm Polymer Optical Fiber (POF) over operating temperature range Up to 200 m (10 MBd) distance and 120 m (50 MBd) distance with 200 m Plastic-Clad Silica (PCS) over operating temperature range Operating temperature range of -40 C to +85 C Compatible with Avago’s Versatile Link family of connectors, for easy termination of fiber Applications Optical Transmitter and Receiver for 50 MBd systems and below: High voltage isolation 5/6 = 650 nm products Horizontal Package Vertical Package Tilted (30°) package Receiver: integrated PIN diode and digitalizing IC with TTL output logic Extension of RS-232 and RS-485 AFBR – x x x x Z 2 = Horizontal Package 3 = Vertical Package 4 = Tilted (30°) Package Transmitter: integrated 650 nm LED and driver IC with TTL input logic Industrial control and factory automation AFBR-xxxxZ - Part number selection guide 1 = Transmitter (TX) 2 = Receiver (RX) Data transmission at signal rates from DC up to 50 MBd AFBR-1629Z AFBR-1639Z AFBR-2529Z AFBR-2539Z Elimination of ground loops Reduces voltage transient susceptibility Application Literature Handling Application Note 1035 (Versatile Link) - AV02-0730EN Versatile Link components are auto-insertable. When wave soldering is performed with Versatile Link components, the optical port plug should be left in to prevent contamination of the port. Do not use reflow solder processes (i.e., infrared reflow or vapor-phase reflow). Nonhalogenated water soluble fluxes (i.e., 0% chloride), not rosin based fluxes, are recommended for use with Versatile Link components. Package and Handling Information The compact Versatile Link package is made of a flameretardant material and uses the same pad layout as a standard, eight-pin dual-in-line package. Horizontal, Vertical, and Tilted (30°) packages are available. These low profile Versatile Link packages are stackable and are enclosed to provide a dust-resistant seal. Snap action simplex, simplex latching, duplex, and duplex latching connectors are offered with simplex or duplex cables. Package Orientation Performance and pinouts for the horizontal, vertical, and tilted (30°) packages are identical. To provide additional attachment support for the vertical Versatile Link housing, the designer has the option of using a selftapping screw through a printed circuit board into a mounting hole at the bottom of the package. For most applications this is not necessary. Package Housing Color Versatile Link components and simplex connectors are color coded to eliminate confusion when making connections. Receiver packages are black and transmitter packages are gray in color respectively. 2 Versatile Link components are moisture sensitive devices and are shipped in a moisture sealed bag. If the components are exposed to air for an extended period of time, they may require a baking step before the soldering process. Refer to the special labeling on the shipping tube for details. Recommended Chemicals for Cleaning/Degreasing Alcohols: methyl, isopropyl, isobutyl. Aliphatics: hexane, heptane. Other: soap solution, 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 does not recommend the use of cleaners that use halogenated hydrocarbons because of their potential environmental harm. Mechanical Dimensions Vertical Module 2 [0.08] Horizontal Module 3.6 [0.14] 5.1 [0.20] 10.2 [0.40] 6.5 [0.26] 10.2 [0.40] 1 [0.04] 18.8 [0.74] 18.1 [0.71] 5.1 [0.20] 6.5 [0.26] 7.6 [0.30] 4.2 [0.17] 18.9 [0.75] 1.3 [0.05] 0.6 [0.02] 2.54 [0.100] 0.5 [0.02] NOTES: 1) Dimensions: mm [in] 2.8 [0.11] MIN .6 0 3] 0.0 [ 1.7 [0.07] 3.3 [0.13] MAX 7.7 [0.30] 3.6[0.14]MIN. 3.8[0.15]MAX. 0.6 [0.03] 7.6 [0.30] 2 [0.08] 1.3 [0.05] 0.5 [0.02] 7.62 [0.300] 2.54 [0.100] 3.8 [0.15] 1.7 [0.07] 2.8 [0.11] NOTES: 1) Dimensions: mm [in] 2) 2) Optional mounting hole for #2 self-tapping-screw (metric equivalent M2.2 x 0.45) 3.8 [0.15] 2 [0.08] Tilted (30°) Module 6.5 [0.26] 10.2 [0.40] A 30° 0.4 [0.02] 2.54 [0.100] 0.5 [0.02] 1.3 [0.05] 4.6 [0.18] 4.6 [0.18] 0.6 [0.03] 6.6 [0.26] 15.2 [0.60] .7 18 4] 7 [0. A 0.7 [0.03] 1.1 [0.05] 8.7 [0.34] 10.1 [0.40] 7.62 [0.300] 2.2 [0.09] NOTES: 1) Dimensions: mm [in] 19.3 [0.76] 3 0.6 3] 0 0. [ Versatile Link Printed Board Layout Dimensions Horizontal Module Vertical Module 7.62 [0.300] 7.62 [0.300] 2.54 [0.100] 2.54 [0.100] 1 ] 4 0.0 [ 2 [ 1 7.7 [0.30] 3 4] 2.25 [0.09] clearance hole for optional vertical mount self-tapping-screw #2 3.8 [0.15] 8 5 1 0.0 4 3 2 1 7.62 [0.300] 4 PCB EDGE 5 1.9 MIN. [0.07] PCB EDGE 3.8 [0.15] NOTES: 8 1.7 [0.07] MIN. 1) Dimensions: mm [in] Footprint - TOP VIEW 7.62 [0.300] 2.54 [0.100] 1 [0 .04] 3 2 1 8.7 [0.34] 4 5 8 PCB EDGE 2.2 MIN. [0.09] NOTES: 1) Dimensions: mm [in] Footprint - TOP VIEW 4 1) Dimensions: mm [in] Footprint - TOP VIEW Tilted (30°) Module NOTES: Interlocked (Stacked) Assemblies (refer to Figure 1) Horizontal packages may be stacked by placing units with pins facing upward. Initially engage the interlocking mechanism by sliding the L bracket body from above into the L slot body of the lower package. Use a straight edge, such as a ruler, to bring all stacked units into uniform alignment. This technique prevents potential harm that could occur to fingers and hands of assemblers from the package pins. Stacked horizontal packages can be disengaged if necessary. Repeated stacking and unstacking causes no damage to individual units. To stack vertical packages, hold one unit in each hand, with the pins facing away and the optical ports on the bottom. Slide the L bracket unit into the L slot unit. The straight edge used for horizontal package alignment is not needed. Stacking Horizontal Modules Tilted (30°) Module Figure 1. Interlocked (stacked) Horizontal, Vertical and Tilted (30°) packages 5 Stacking Vertical Modules TX RX 4 3 2 1 4 3 2 1 Pin Description Transmitter Fiber port facing front, pins downward, 1 = Rightmost pin to 4 = Leftmost pin Pin Name Function/Description Notes 1 VCCT Transmitter Power 3.3 V ± 5% or 5 V ± 5% 2 No Pin No physical pin is available 3 VEET Transmitter Ground 4 Data In Transmitter Data Input 1, 2 5 Housing Pin Physical pin is available, recommended to chassis GND 3 8 Housing Pin Physical pin is available, recommended to chassis GND 3 Pin Description Receiver Fiber port facing front, pins downward, 1 = Rightmost pin to 4 = Leftmost pin Pin Name Function/Description Notes 1 2 Data Out Receiver Data Output 2 VEER Receiver Ground 3 VCCR Receiver Power 3.3 V ± 5% or 5 V ± 5% 4 Pin No function, physical pin is available, recommended to signal GND 4 5 Housing Pin Physical pin is available, recommended to chassis GND 3 8 Housing Pin Physical pin is available, recommended to chassis GND 3 Notes: 1. Logic 1 input will turn the light on and the logic 0 will turn the light off for AFBR-16x4Z. Logic 1 input will turn the light off and the logic 0 will turn the light on for AFBR-16x9Z. 2. TTL compatible data input and output. 3. Pin 5 and 8 are for mounting and retaining purposes, and should be connected to chassis GND. 4. It is recommended to connect this pin to signal GND. 6 Regulatory Compliance Feature Test Method Performance Electrostatic Discharge (ESD) to the Electrical Pins Human Body Model MIL-STD-883 Method 3015 Min 2000 V Eye Safety IEC 60825-1, 2, Class 1 Specified Link Performance, TA = -40 C to +85 C, 50 MBd Parameter Min Max Unit Condition Notes Link Distance with Standard POF cable 0.1 50 meters -40 C to +85 C 1, 3 Link distance with 200 m PCS (10 MBd) 0.1 200 meters -40 C to +85 C 2, 3 Link distance with 200 m PCS (50 MBd) 0.1 120 meters -40 C to +85 C 2, 3 Notes: 1. HFBR-R/EXXYYYZ is the part number for 1 mm POF. Worst-case attenuation used (0.27 dB/m for standard loss POF cable from -40 C to +85 C at 660 nm). 2. PCS, worst-case attenuation (12 dB/km from -40 C to +85 C at 650 nm). 3. The optical link performance is guaranteed only with transmitters AFBR-16xxZ and receivers AFBR-26x4Z/25x9Z. Gnd 5 GND NC VCC 4 TTL Input 3 2 1 8 Gnd TX Data In VEE L1 GND 1 PH Pull down resistor 4.7 kOhm GND GND C3 100 nF C1 10 PF Gnd 8 Gnd RX GND VEE Data Out GND L2 4 VCC 1 PH 3 C4 100 nF 2 C2 10 PF C6 10 PF 1 GND GND TTL Output Figure 2. Recommended Transmitter and Receiver Application Circuit 7 C5 10 PF GND 5 GND NC VCC VCC GND GND Absolute Maximum Ratings Parameter Symbol Min Typical Max Unit Notes Storage Temperature Ts -40 85 °C 1 Ambient Temperature Tc -40 85 °C 1 Relative Humidity RH 0 85 % 1 Supply Voltage VCCT /VCCR -0.5 6 V 1 Data Input Voltage VIN -0.5 Vcc+0.5 V 1 Data Output Current IO 10 mA 1 50 MBd Data Rate DC 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. Recommended Operating Conditions Parameter Symbol Min Typical Max Unit Notes Ambient Temp TA -40 25 85 °C 2 Supply Voltage VCCT/VCCR 3.135 3.3 3.465 V 2 4.75 5 5.25 V 2 Notes: 2. 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. Process Compatibility Parameter Symbol Solder Environment Max Unit Notes TSOLD 260 °C 3, 5, 6 tSOLD 10 sec 4, 5, 6 Notes: 3. Maximum temperature refers to peak temperature. 4. Maximum time refers to time spent at peak temperature. 5. Solder surface to be at least 1mm below lead frame stops. 6. Product is moisture sensitive level 3. 8 Min Typical AFBR-16xxZ Transmitter The AFBR-16xxZ transmitter incorporates a 650 nm LED and integrated driver IC in a light gray, nonconductive plastic Versatile Link housing. Its input data is compatible with TTL logic level. This transmitter can operate from DC to 50 MBd with any kind of data pattern using 1 mm Polymer Optical Fiber (POF). Within the specified ranges AFBR-16x4Z and AFBR-16x9Z devices will support a BER < 10E-9. Transmitter Electrical Characteristics (TA = -40 C to +85 C, VCCT = 3.3 V ± 5% or 5 V ± 5%) Parameter Symbol Supply Current (Optical Power ON) ICCT Input Voltage – Low VIL Input Voltage – High VIH Data Input Capacitance CIN Data Input Resistance RIN Propagation Delay tTD Min Typical Max Unit Notes 21 31 mA 1 -0.3 0.8 V 2 2.0 Vcc+0.3 V 2 7 pF 2 k 30 ns Transmitter Optical Characteristics (TA = -40 C to +85 C, VCCT = 3.3 V ± 5% or 5 V ± 5%) Parameter Symbol Min Typical Max Unit Notes Output Optical Power (peak), 1 mm POF PN -4.5 -2 +2 dBm 3 Output Optical Power (peak), PCS (200 μm) PN -16.5 -13 -9 dBm 3 Output Optical Power (Average), OFF PS -50 dBm Extinction Ratio ER 10 Peak Wavelength c 630 dB 685 nm Rise Time (20%–80%) tRT 5 ns Fall Time (20%–80%) tFT 5 ns Pulse Width Distortion PWD -3 +3 ns 4, 5 Pulse Width Distortion of first pulse PWD -5 +3 ns 5, 6 Notes: 1. For any type of data between DC and 50 Mbd. Typical value 21 mA for PRBS-7 pattern at 25 C at 5 V and 50 Mbaud. 2. Standard TTL compatible input. 3. Measured with polished connector end face: after 1 meter 1 mm POF, NA = 0.5, or 200 m PCS, NA = 0.37. 4. Pulse width is measured at 50% threshold using a rising edge trigger tested with PRBS-7 pattern 5. Electrical input pulse width is determined at 1.5 V and dU/dt between 1 V and 2 V shall not be less than 1 V/ns. 6. The first pulse is shorter as the LED is completely discharged. This helps to mitigate the increase of pulse width of the first pulse of the Receiver 9 AFBR-26x4Z/25x9Z Receiver The AFBR-26x4Z/25x9Z receiver consists of a digitalizing IC with integrated photodiode to produce an output level that is compatible with TTL logic. The integrated photodiode and the following amplifier uses a fully differential approach with an active and a passive area for an improved EMI performance. Within the specified ranges AFBR-25x9Z and AFBR26x4Z devices will support a BER <10E-9. Receiver Electrical Characteristics (TA = -40 °C to +85 °C, VCCT = 3.3 V ± 5% or 5 V ± 5%) Parameter Symbol Min Typical Max Unit Supply Current ICCR Data Output Voltage – Low VOL Data Output Voltage – High VOH Rise Time (10%–90%) tRR Fall Time (10%–90%) tFR Pulse Width Distortion PWD -4 Pulse Width Distortion 1st to 3rd pulse PWDinit -5 Propagation Delay Max. Initiation time after Power up Notes 20 30 mA -0.3 0.4 V 1, 3 2.5 VCCR+0.3 V 1, 3 5 ns 2, 3 5 ns 2, 3 +4 ns 3, 6, 7, 8, 11 +8 ns 3, 8, 9, 11 tRD 30 ns TINT 15 ms 12 Max Unit Notes +2 dBm 3 dBm 3, 10 dBm 3 dBm 3 Receiver Optical Characteristics (TA = -40 °C to +85 °C, VCCT = 3.3 V ± 5% or 5 V ± 5%) Parameter Symbol Min Input Optical Power (Peak), 1 mm POF PIN -22 Input Optical Power (Peak) Off-State, 1 mm POF PIN_Off -40 Input Optical Power (Peak), PCS (200 m) PIN -25 Input Optical Power (Peak) Off-State, PCS (200 m) PIN_Off Optical Spectrum Range Typical -1 -44 630 685 nm Notes: 1. Standard TTL output. 2. Measured with RL = 50 k and CL = 15 pF 3. Guaranteed only if optical input signal to the receiver is generated by AFBR-16xxZ, with ideal alignment to photo diode using 1mm POF (NA=0.5). 6. Optical input signal of 50 MBd, PRBS 27 -1 pattern and 50% duty cycle. 7. Pulse width is measured at 50% threshold using a rising edge trigger and PRBS 27-1 pattern. 8. If data rate is below 1MBd the pulse width distortion would be equal to the pulse width distortion of the 1st to 3rd pulses for higher datarates. 9. The threshold of the 1st pulse of a data sequence is difficult to adjust and therefore the pulse width distortion up to the 3rd pulse is higher than for all other pulses (worst case for the 1st pulse). This strongly depends on the quality of the rising and falling edge of the optical input. The faster the edges the smaller the pulse width variation. Furthermore lower data rates would result in the same issue as all the pulse become 1st pulses. 10. Output low for AFBR-26x4Z and Output high for AFBR-25x9Z. 11. Because of optical pulse width spreading, the PWD limits have to be increased by 0.1 ns for each 10 m fiber length. 12. Starting point is when supply voltage passes ~2.8 V. For product information and a complete list of distributors, please go to our web site: www.broadcom.com. Broadcom, the pulse logo, Connecting everything, Avago Technologies, and the A logo are the trademarks of Broadcom in the United States, certain other countries and/or the EU. Copyright © 2005-2016 Broadcom. All Rights Reserved. The term "Broadcom" refers to Broadcom Limited and/or its subsidiaries. For more information, please visit www.broadcom.com. Broadcom reserves the right to make changes without further notice to any products or data herein to improve reliability, function, or design. Information furnished by Broadcom is believed to be accurate and reliable. However, Broadcom does not assume any liability arising out of the application or use of this information, nor the application or use of any product or circuit described herein, neither does it convey any license under its patent rights nor the rights of others. AV02-4369EN - July 25, 2016