* 11 dB Multimode 1300 nm LED Fast Ethernet/FDDI/ATM 170 MBd 1x9 Transceiver V23809-C8-C10 Dimensions in (mm) inches (Lead cross section and standoff size) (0.63 0.2) .025 .008 (8.6 max) .340 max (10 -0.25) .393 -.009 View Z (3 0.2) .118 .008 11x (0.46 0.05) .02 .002 (3.8 max) .150 max PC board 0.3 M A .012 M A 0.1 M .004 M 2x (1.4 -0.05) (2.8 max) .055 -.002 .110 max Z 9x .031 .004 .7 -0.1) 5.2 (.75) .205 .030.028 -.004 process plug (dashed) 8x 2.54=20.32 8x .100 =.800 1 2 3 4 5 6 7 8 9 DUPLEX SC RECEPTACLE 8x 2.54=20.32 8x .100 =.800 12.7 .500 Tx (2.54) .100 (2.54) .100 20.32 .800 A Top view 0.1 M .004 M Rx (25.25 0.05) .994 .002 11x (0.6 0.1) .024 .004 0.3 M A .012 M A 9x (0.8 0.1) Optical Centerline (1 0.1) .04 .039 20.32 .800 (15.88 0.5) .625 .020 (11 max) .433 max (1.9 -0.1) 2x .075 -.004 Footprint (38.6 0.15) 1.52 .006 APPLICATIONS * ATM switches/bridges/routers * Fast Ethernet, FDDI * SDH STM-1 based systems * High speed computer links * Local area networks * Switching systems Absolute Maximum Ratings FEATURES * Compliant with Fast Ethernet, FDDI, Fibre Channel, ATM/SONET standards * Compact integrated transceiver unit with duplex SC receptacle * Single power supply with 3.0 V to 5.5 V range * Extremely low power consumption < 0.7 W at 3.3 V * PECL differential inputs and outputs * System optimized for 62.5/50 m graded index fiber * Industry standard multisource footprint * Very low profile for high slot density * Wave solderable and washable with process plug inserted * Testboard available * UL-94 V-0 certified * ESD Class 1 per MIL-STD 883D Method 3015.7 (March 89) * Compliant with FCC (Class B) and EN 55022 * For distances of up to 2 km on multimode fiber Fiber Optics Exceeding any one of these values may destroy the device immediately. Supply Voltage (VCC-VEE)....................................... -0.5 V to 7 V Data Input Levels (PECL) (VIN)..................................... VEE-VCC Differential Data Input Voltage ............................................... 3 V Operating Ambient Temperature (TAMB) ................. 0C to 85C Storage Ambient Temperature ............................ -40C to 85C Soldering Conditions, Temp/Time (TSOLD/tSOLD) (MIL-STD 883C, Method 2003) ............................ 270 C/ 10 s ESD Resistance (all pins to VEE, human body) .................. 1.5 kV Output Current (IO) ........................................................... 50 mA * Available also as 8 dB V23809-C8-C11 on request. AUGUST 2001 TECHNICAL DATA The electro-optical characteristics described in the following tables are valid only for use under the recommended operating conditions. DESCRIPTION This data sheet describes the Infineon Fast Ethernet/FDDI/ATM transceiver - part of Infineon Multistandard Transceiver Family. It is fully compliant with the Asynchronous Transfer Mode (ATM) OC-3 standard, the Fiber Distributed Data Interface (FDDI) Low Cost Fiber Physical Layer Medium Dependent (LCFPMD) draft standard(1), and the FDDI PMD standard(2). Recommended Operating Conditions Parameter Symbol Min. ATM was developed because of the need for multimedia applications, including real time transmission. The data rate is scalable and the ATM protocol is the basis of the broadband public networks being standardized in the International Telegraph and Telephone Consultative Committee (CCITT). ATM can also be used in local private applications. Ambient Temperature TAMB 0 Power Supply Voltage VCC-VEE 3 Supply Current 3.3 V ICC FDDI is a Dual Token Ring standard developed in the U.S. by the Accredited National Standards Committee (ANSC) X3T9, within the Technical Committee X3T9.5. It is applied to the local area networks of stations, transferring data at 100 Mbit/s with a 125 MBd transmission rate. LCF FDDI is specially developed for short distance applications of up to 500 m (fiber-to-the-desk) as compared to 2 km for backbone applications. Data Input High Voltage VIH-VCC -1165 -880 Data Input Low Voltage VIL-VCC -1810 -1475 Threshold Voltage VBB-VCC -1380 -1260 Input Data Rise/Fall, 20%-80% tR, tF 1.3 Fast Ethernet was developed because of the higher bandwidth requirement in local area networking. It is based on the proven effectiveness of millions of installed Ethernet systems. Data High Time(2) ton 1000 Output Current lO 25 mA Input Duty Cycle Distortion tDCD 1.0 ns Input Data Dependent Jitter tDDj Input Random Jitter tRJ Input Center Wavelength lC Electrical Output Load(3) RL Supply Current 5 Notes EN 61000-4-2 IEC 61000-4-2 Discharges of 15 kV with an air discharge probe on the receptacle cause no damage. Immunity: Radio Frequency Electromagnetic Field EN 61000-4-3 IEC 61000-4-3 With a field strength of 10 V/m rms, noise frequency ranges from 10 MHz to 1 GHz Eye Safety IEC 825-1 Class 1 mA 260 0.4 mV ns 0.76 1260 1380 50 nm 2. To maintain good LED reliability, the device should not be held in the ON state for more than the specified time. Normal operation should be done with 50% duty cycle. Regulatory Compliance Immunity: Electrostatic Discharge V 1. For VCC-VEE (min., max.). 50% duty cycle. The supply current (ICC2+ICC3) does not include the load drive current (Icc1). Add max. 45 mA for the three outputs. Load is 50 into VCC-2V. 2. FDDI Token Ring, Physical Layer Medium Dependent (PMD) ANSI X3.166-1990 American National Standard. ISO/IEC 9314-3: 1990. FCC 47 CFR Part 15, Noise frequency Class B range: 30 MHz to EN 55022 Class B 40 GHz CISPR 22 5.5 230 Notes 1. FDDI Token Ring, Low Cost Fiber Physical Layer Medium Dependent (LCF-PMD) ANSI X3T9.5 / 92 LCF-PMD / Proposed Rev. 1.3, September 1, 1992. American National Standard. Electromagnetic Interference (EMI) C Receiver The inputs/outputs are PECL compatible and the unit operates from a 3.0 V to 5.5 V power supply. As an option, the data output stages can be switched to static levels during absence of light, as indicated by the Signal Detect function. It can be directly interfaced with available chipsets. Standard V(1) Units 70 Transmitter The Infineon multimode transceiver is a single unit comprised of a transmitter, a receiver, and an SC receptacle. This design frees the customer from many alignment and PC board layout concerns. The modules are designed for low cost applications. Feature Typ. Max. 3. To achieve proper PECL output levels the 50 termination should be done to VCC-2 V. For correct termination see the application notes. Comments Fiber Optics V23809-C8-C10, MM 1300 nm LED Fast Ethernet/FDDI/ATM 170 MBd 1x9 Trx 2 Transmitter Electro-Optical Characteristics Transmitter Symbol Min. Data Rate DR Launched Power (Average) into 62.5 m Fiber for -C8-C10(1, 2) PO Launched Power (Average) into 62.5 m Fiber for -C8-C11(1, 2) Center Wavelength(2, 3) C Spectral Width (FWHM)(2, 4) Dl Output Rise/Fall Time, 10%-90%(2, 5) tR, tF Temperature Coefficient of Optical Output Power Typ. -20 -16 -22 -17 Receiver Electro-Optical Characteristics Max. Units Receiver Symbol Min. 5(1) 170 MBd Data Rate DR -14 dBm Sensitivity Average Power)(2) PIN 1360 nm 170 0.6 -33 Sensitivity (Average Power) Center(3) Max. 170 MBd -31 dBm -14 ns -11 Duty Cycle Distortion(4, 5) tDCD 1 Deterministic Jitter(5, 6) tDJ 1 Random Jitter(5, 7) tRJ Signal Detect Assert Level(8) PSDA -42.5 -30 -31.5 2.5 ns TCp 0.03 dB/C Extinction Ratio (Dynamic)(2, 6) ER 10 % Signal Detect Deassert Level(9) PSDD -45 Optical Power Low(7) PTD -45 dBm Signal Detect Hysteresis PSDA- PSDD 1.0 Output Low Voltage(10) VOL-VCC -1810 -1620 Output High Voltage(10) VOH-VCC -1025 -880 Output Data Rise/Fall Time, 20%-80% tR, tF 1.3 Overshoot OS 10 % Duty Cycle Distortion(8, 9) tDCD 0.6 ns Data Dependent Jitter(8, 10) tDDJ 0.3 Random Jitter(8, 11) tRJ 0.6 Notes Units -35.5 Saturation (Average PSAT Power)(3) 1270 Typ. Output SD Rise/Fall Time, 20%-80% dBm dB mV ns 40 1. Measured at the end of 5 meters of 62.5/125/0.275 graded index fiber using calibrated power meter and a precision test ferrule. Cladding modes are removed. Values valid for EOL and worst-case temperature. Notes 2. The input data pattern is a 12.5 MHz square wave pattern. 1. Pattern: Manchester coding / NRZI (no scrambling) 3. Center wavelength is defined as the midpoint between the two 50% levels of the optical spectrum of the LED. 2. For a bit error rate (BER) of less than 1x10E-12 over a receiver eye opening of least 1.5 ns. Measured with a 223-1 PRBS at 155 MBd. 4. Spectral width (full width, half max) is defined as the difference between 50% levels of the optical spectrum of the LED. 3. For a BER of less than 1x10E-12. Measured in the center of the eye opening with a 223-1 PRBS at 155 MBd. 5. 10% to 90% levels. Measured using the 12.5 MHz square wave pattern with an optoelectronic measurement system (detector and oscilloscope) having 3 dB bandwidth ranging from less than 0.1 MHz to more than 750 MHz. 4. Measured at an average optical power level of -20 dBm with a 62.5 MHz square wave. 5. All jitter values are peak-to-peak. RX output jitter requirements are not considered in the ATM standard draft. In general the same requirements as for FDDI are met. 6. Extinction Ratio is defined as PL/PH x 100%. Measurement system as in Note 5. 6. Measured at an average optical power level of -20 dBm. 7. Optical Power Low is the output power level when a steady state low data pattern (FDDI Quiet Line state) is used to drive the transmitter. Value valid <1 ms after input low. 7. Measured at -33 dBm average power. 8. Test method as for FDDI-PMD. Jitter values are peak-to-peak. 8. An increase in optical power through the specified level will cause the SIGNAL detect output to switch from a Low state to a High state. 9. Duty Cycle Distortion is defined as 0.5 [(width of wider state) minus (width of narrower state)]. It is measured with stream of Idle Symbols (62.5 MHz square wave). 9. A decrease in optical power through the specified level will cause the SIGNAL detect output to switch from a High state to a Low state. 10.Measured with the same pattern as for FDDI-PMD. 10. PECL compatible. Load is 50 into VCC-2 V. Measured under DC conditions. For dynamic measurements a tolerance of 50 mV should be added for VCC=5 V. 11. Measured with the Halt Line state (12.5 MHz square wave). Fiber Optics V23809-C8-C10, MM 1300 nm LED Fast Ethernet/FDDI/ATM 170 MBd 1x9 Trx 3 Pin Description Pin Name Level/Logic Pin# Description RxVEE Rx Ground Power Supply 1 Negative power supply, normally ground RD Rx Output Data PECL Output RDn 2 Receiver output data 3 Inverted receiver output data RxSD RX Signal Detect PECL Output active high 4 High level on this output shows there is an optical signal RxVCC Rx +3.3 V...5 V Power Supply Positive power supply, +3.3 V...5 V TxVCC Tx +3.3 V...5 V TxDn Tx Input Data PECL Input 7 8 Transmitter input data TxVEE Tx Ground Power Supply 9 Negative power supply, normally ground Case Support Not Connected S1/S2 Support stud, not connected 5 6 TxD Inverted transmitter input data APPLICATION NOTE Multimode 1300 nm ATM 1x9 Transceiver C1/3=4700 nF (optional) VCC-Tx VCC-Rx VCC Rx VCC C2/4=4700 nF L1 GND GND R5 82R 82R R3 R1 82R 1 82R R7 9 L1/2=15000 nH (L2 is optional) VCC C1 RD RDN SD TXD TXDN 100 127 R2/4 130 100 83 R5/7 82 100 127 R6/8 130 100 83 GND GND Transceiver 130R R8 82 VCC-Rx R6 130R R1/3 R9 200R 3.3 V 130R R4 4V R2 130R 5V GND GND GND GND GND VCC Tx L2 VCC-Tx R in Ohm C2 C3 GND C4 GND DC coupling between ECL gates R9=200 Ohm A GND plane under the module is recommended for good EMI and sensitivity performance. The power supply filtering is required for good EMI performance. Use short tracks from the inductor L1/L2 to the module VCC-RX/VCC-TX. Fiber Optics V23809-C8-C10, MM 1300 nm LED Fast Ethernet/FDDI/ATM 170 MBd 1x9 Trx 4 APPLICATION NOTE Multimode 1300 nm LED Transceiver Solutions for connecting an Infineon 3.3 V Fiber Optic Transceiver to a 5.0 V Framer-/Phy-Device. Figure 1. Common GND Figure 1a. Circuitry for SD (Differential) and Common GND VCC 5.0 V VCC 3.3 V VCC 39K 127 VCC VCC 5.0 V 26K SD Infineon Fiber Optic 3.3 V Transceiver VCC 100 nF Framer/Phy Clock Data Recovery Out Tx In 83 500 100 nF 500 Rx Out 127 Data In 180 VCC 68 VCC 3.3 V 83 Framer/Phy SD Clock Recovery 5V SD Figure 1b. Circuitry for SD (Single Ended) and Common GND VCC 5.0 V VCC 3.3 V SD Out VCC VCC 18K SD In Infineon Fiber Optic Transceiver 1.8 V Inputs and outputs are differential and should be doubled. Signal Detect (SD) is single ended (if used). SD In 1 510 Framer/Phy Clock Recovery 5V SD Infineon Out Fiber Optic 3.3 V Transceiver 1 Zener-Diode 1.8 V Figure 2. Common VCC Framer/Phy Clock Data Recovery Out Infineon Fiber Optic Transceiver GND 3.3 V Tx In 130 Inputs and outputs are differential and should be doubled. Signal Detect (SD) is single ended. VCC Rx Out 83 Data In 82 VCC 127 VCC SD GND 5.0 V In 200 SD Out GND 5.0 V GND 3.3 V GND 3.3 V Fiber Optics V23809-C8-C10, MM 1300 nm LED Fast Ethernet/FDDI/ATM 170 MBd 1x9 Trx 5 Published by Infineon Technologies AG Warnings (c) Infineon Technologies AG 2001 All Rights Reserved Due to technical requirements components may contain dangerous substances. For information on the types in question please contact your Infineon Technologies offices. Infineon Technologies Components may only be used in life-support devices or systems with the express written approval of Infineon Technologies, if a failure of such components can reasonably be expected to cause the failure of that life-support device or system, or to affect the safety or effectiveness of that device or system. Life support devices or systems are intended to be implanted in the human body, or to support and/or maintain and sustain and/or protect human life. If they fail, it is reasonable to assume that the health of the user or other persons may be endangered. Attention please! The information herein is given to describe certain components and shall not be considered as warranted characteristics. Terms of delivery and rights to technical change reserved. We hereby disclaim any and all warranties, including but not limited to warranties of non-infringement, regarding circuits, descriptions and charts stated herein. Infineon Technologies is an approved CECC manufacturer. Information For further information on technology, delivery terms and conditions and prices please contact the Infineon Technologies offices or our Infineon Technologies Representatives worldwide - see our webpage at www.infineon.com/fiberoptics Infineon Technologies AG * Fiber Optics * Wernerwerkdamm 16 * Berlin D-13623, Germany Infineon Technologies, Inc. * Fiber Optics * 1730 North First Street * San Jose, CA 95112, USA Infineon Technologies K.K. * Fiber Optics * Takanawa Park Tower * 20-14, Higashi-Gotanda, 3-chome, Shinagawa-ku * Tokyo 141, Japan