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| 19-2927; Rev 1; 8/03 2.7Gbps SFP Transimpedance Amplifiers with RSSI General Description The MAX3744/MAX3745 transimpedance amplifiers provide a compact, low-power solution for communication up to 2.7Gbps. They feature 330nA input-referred noise at 2.1GHz bandwidth (BW) with 0.85pF input capacitance. The parts also have >2mAP-P AC input overload. Both parts operate from a single +3.3V supply and consume 93mW. The MAX3744/MAX3745 are in a compact 30-mil x 50-mil die and require no external compensation capacitor. A space-saving filter connection is provided for positive bias to the photodiode through an on-chip 580 resistor to V CC. These features allow easy assembly into a low-cost TO-46 or TO-56 header with a photodiode. The MAX3744 and MAX3748A receiver chip set provides an RSSI output using a Maxim-proprietary* interface technique. The MAX3744 preamplifier, MAX3748A postamplifier, and DS1858/DS1859 SFP controller meet all the SFF-8472 digital diagnostic requirements. o Up to 2.7Gbps (NRZ) Data Rates o RSSI Implementation in 4-Pin TO46 Header (MAX3744) o 10psP-P Deterministic Jitter for <100AP-P Input Current o 330nARMS Input-Referred Noise at 2.1GHz Bandwidth o 28mA Supply Current at +3.3V o 2GHz Small-Signal Bandwidth o 2.0mAP-P AC Overload o Die Size: 30 mils x 50 mils Features MAX3744/MAX3745 Applications Up to 2.7Gbps SFF/SFP Optical Receivers Optimized for Small-Form-Factor Pluggable (SFP) Optical Receivers *Patent pending PART MAX3744E/D MAX3745E/D Ordering Information TEMP RANGE -40C to +85C -40C to +85C PIN-PACKAGE Dice** Dice** **Dice are guaranteed to operate from -40C to +85C, but are tested only at TA = +25C. Typical Application Circuit SFP OPTICAL RECEIVER 400pF 400pF VCC VCC FILTER OUT+ MAX3744 0.1F OUT+ IN+ HOST BOARD IN GND OUT- MAX3748A INOUTRSSI DISABLE LOS 0.1F VCC = 3.3V 4.7k TO 10k 4-PIN TO CAN 3.3k MOD-DEF1 DS1858/ DS1859 MOD-DEF2 ________________________________________________________________ Maxim Integrated Products 1 For pricing, delivery, and ordering information, please contact Maxim/Dallas Direct! at 1-888-629-4642, or visit Maxim's website at www.maxim-ic.com. 2.7Gbps SFP Transimpedance Amplifiers with RSSI MAX3744/MAX3745 ABSOLUTE MAXIMUM RATINGS Power-Supply Voltage (VCC) .................................-0.5V to +6.0V Continuous CML Output Current (OUT+, OUT-) ............................................. -25mA to +25mA Continuous Input Current (IN)...............................-4mA to +4mA Continuous Input Current (FILTER).......................-8mA to +8mA Operating Junction Temperature Range (TJ) ....-55C to +150C Storage Ambient Temperature Range (TSTG) ...-55C to +150C Die Attach Temperature...................................................+400C Stresses beyond those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. ELECTRICAL CHARACTERISTICS (VCC = +2.97V to +3.63V and TA = -40C to +85C. Typical values are at VCC = +3.3V, source capacitance (CIN) = 0.85pF, and TA = +25C, unless otherwise noted.) (Notes 1, 2) PARAMETER Supply Current Input Bias Voltage Input Overload (Note 3) CIN = 0.85pF, BW = 933MHz CIN = 0.85pF, BW = 2.1GHz Input-Referred Noise IN CIN = 0.85pF, BW = 18GHz CIN = 0.85pF, BW = 933MHz CIN = 0.6pF, BW = 2.1GHz CIN = 0.6pF, BW = 18GHz Differential Transimpedance Small-Signal Bandwidth (Note 3) Low-Frequency Cutoff Deterministic Jitter (Notes 3, 5) Filter Resistance Differential Output Resistance (OUT+, OUT-) Maximum Differential Output Voltage VOD Input > 50AAVE, output termination 50 to VCC (output in limited state) BW Differential output, IIN = 40AAVE -3dB, CIN = 0.6pF -3dB, CIN = 0.85pF -3dB, input current = 20AAVE (Note 3) 100AP-P < input 2.1Gbps, K28.5 pattern 2mAP-P 2.7Gbps, 231-1 pattern 10AP-P < input 100AP-P 2.1Gbps, K28.5 pattern 2.7Gbps, 231-1 pattern 510 85 220 14 24 10 20 580 100 280 690 115 400 mVP-P 16 2.8 1.8 1.6 3.5 2 1.8 30 31 psP-P 206 300 380 550 4.5 k GHz kHz 2 206 330 430 620 nARMS SYMBOL ICC CONDITIONS Including CML output current (IIN = 0) MIN TYP 28 MAX 41 1.0 UNITS mA V mAP-P DJ 2 _______________________________________________________________________________________ 2.7Gbps SFP Transimpedance Amplifiers with RSSI ELECTRICAL CHARACTERISTICS (continued) (VCC = +2.97V to +3.63V and TA = -40C to +85C. Typical values are at VCC = +3.3V, source capacitance (CIN) = 0.85pF, and TA = +25C, unless otherwise noted.) (Notes 1, 2) PARAMETER Single-Ended Output CommonMode Minimum Level (MAX3744) Output Data Transition Time Differential Output Return Loss Power-Supply Noise Rejection RSSI Gain (MAX3744) RSSI Gain Stability (MAX3744) PSNR ARSSI SYMBOL CONDITIONS Relative to VCC, IIN = 1mAAVE Input > 200AP-P 20% to 80% rise/fall time (Note 3) Frequency 1GHz 1GHz < frequency 2GHz IIN = 0 (Note 6) (Note 7) 10log(ARSSI/ARSSI-NOM) where ARSSI-NOM = ARSSI at 3.3V, +25C (Note 3) f < 1MHz 1MHz f < 10MHz MIN 540 TYP 490 80 17 10 46 34 21 0.24 140 MAX UNITS mV ps dB dB A/A dB MAX3744/MAX3745 Note 1: Die parameters are production tested at room temperature only, but are guaranteed by design and characterization from -40C to +85C. Note 2: Source capacitance represents the total capacitance at the IN pad during characterization of the noise and bandwidth parameters. Note 3: Guaranteed by design and characterization. Note 4: Input-referred noise is: RMS output noise Gain at f = 100MHz Note 5: Deterministic jitter is the sum of pulse-width distortion (PWD) and pattern-dependent jitter (PDJ). Note 6: Power-supply noise rejection PSNR = -20log(VOUT / VCC), where VOUT is the differential output voltage and VCC is the noise on VCC. Note 7: IOUT _ CM (IIN = 400A) - IOUT _ CM (IIN = 0A) ARSSI = 400A IOUT + + IOUT - where IOUT _ CM = 2 RSSI range is from IIN = 6A to 500A _______________________________________________________________________________________ 3 2.7Gbps SFP Transimpedance Amplifiers with RSSI MAX3744/MAX3745 Typical Operating Characteristics (VCC = +3.3V, CIN = 0.85pF, TA = +25C, unless otherwise noted.) INPUT-REFERRED NOISE vs. TEMPERATURE MAX3744 toc01 INPUT-REFERRED NOISE vs. TEMPERATURE BW = 2.1GHz INPUT-REFERRED NOISE (nARMS) 700 600 500 CIN = 1.5pF 400 CIN = 0.85pF 300 CIN = 0.5pF 200 MAX3744 toc02 FREQUENCY RESPONSE MAX3744 toc03 800 UNFILTER INPUT-REFERRED NOISE (nARMS) 700 600 CIN = 1.5pF 500 400 300 200 -40 -20 0 20 40 60 80 CIN = 0.85pF CIN = 0.5pF 800 75 70 GAIN (dB) 65 60 55 50 -40 -20 0 20 40 60 80 100 10M 100M 1G 10G TEMPERATURE (C) FREQUENCY (Hz) 100 TEMPERATURE (C) DETERMINISTIC JITTER vs. INPUT AMPLITUDE MAX3744 toc04 SMALL-SIGNAL TRANSIMPEDANCE vs. TEMPERATURE MAX3744 toc05 EYE DIAGRAM INPUT = 20AP-P, DATA RATE = 2.1Gbps MAX3744 toc06 50 75 K28-5 PATTERN DETERMINISTIC JITTER (psP-P) TRANSIMPEDANCE (dB ) 40 70 5mV/div 65 30 2.7Gbp SONET 20 2.1Gbps FIBRE CHANNEL 10 0 0.01 0.1 1 10 INPUT AMPLITUDE (mAP-P) 60 -40 -20 0 20 40 60 80 100 60ps/div TEMPERATURE (C) EYE DIAGRAM INPUT = 20AP-P, DATA RATE = 2.7Gbps MAX3744 toc07 EYE DIAGRAM INPUT = 2mAP-P, DATA RATE = 2.1Gbps MAX3744 toc08 EYE DIAGRAM INPUT = 2mAP-P, DATA RATE = 2.7Gbps MAX3744 toc09 223-1 PATTERN K28-5 PATTERN 223-1 PATTERN 6mV/div 30mV/div 30mV/div 60ps/div 60ps/div 60ps/div 4 _______________________________________________________________________________________ 2.7Gbps SFP Transimpedance Amplifiers with RSSI Typical Operating Characteristics (continued) (VCC = +3.3V, CIN = 0.85pF, TA = +25C, unless otherwise noted.) SUPPLY CURRENT vs. TEMPERATURE MAX3744 toc10 MAX3744 toc11 MAX3744/MAX3745 DIFFERENTIAL S22 vs. FREQUENCY 0 -5 MAX3744 -10 S22 (dB) -15 -20 -25 -30 0 500 1000 1500 2000 2500 3000 3500 4000 FREQUENCY (MHz) MAX3745 70 60 SUPPLY CURRENT (mA) 50 40 30 20 10 0 -40 -20 DC TRANSFER FUNCTION (VFILT = 0V) 150 OUTPUT VOLTAGE (mVP-P) 100 50 0 -50 MAX3744 toc12 200 -100 -150 -200 0 20 40 60 80 100 -100 -50 0 50 100 TEMPERATURE (C) INPUT CURRENT (mAP-P) RSSI MAX3744, MAX3748A MAX3744 toc13 BANDWIDTH vs. TEMPERATURE MAX3744 toc14 EYE DIAGRAM TEMPERATURE = +100C INPUT = 20AP-P DATA RATE = 2.7Gbps MAX3744 toc15 550 500 MAX3748 RSSI OUTPUT (A) 450 400 350 300 250 200 150 0 4.0 3.5 3dB BANDWIDTH (GHz) 3.0 2.5 2.0 1.5 1.0 0.5 0 -40 -20 0 20 40 60 80 CIN = 0.6pF TA = -40C 223-1 PRBS TA = +85C 6mV/div 500 1000 1500 2000 100 60ps/div AVERAGE INPUT CURRENT (A) TEMPERATURE (C) _______________________________________________________________________________________ 5 2.7Gbps SFP Transimpedance Amplifiers with RSSI MAX3744/MAX3745 Pin Description MAX3744/ MAX3745 BOND PAD 1, 3 2, 7 4 5 6, 10 8 NAME VCC N.C. IN FILTER GND OUTSupply Voltage No Connection TIA Input. Signal current from photodiode flows into this pin. Provides bias voltage for the photodiode through a 580 resistor to VCC. When grounded, this pin disables the DC cancellation amplifier to allow a DC path from IN to OUT+ and OUT- for testing. Supply Ground Inverting Data Output. Current flowing into IN causes the voltage at OUT- to decrease. For the MAX3744, the common mode between OUT+ and OUT- is proportional to the average input current. Noninverting Data Output. Current flowing into IN causes the voltage at OUT+ to increase. For the MAX3744, the common mode between OUT+ and OUT- is proportional to the average input current. FUNCTION 9 OUT+ MAX3744 RF TRANSIMPEDANCE AMPLIFIER IN 50 DC CANCELLATION CIRCUIT FILTER 50 OUT+ OUTVCC IN RF TRANSIMPEDANCE AMPLIFIER 50 VCC 50 OUT+ OUT- VCC DC CANCELLATION CIRCUIT FILTER RSSI MAX3745 Figure 1. Functional Diagram Detailed Description The MAX3744/MAX3745 are transimpedance amplifiers designed for up to 2.7Gbps SFF/SFP transceiver modules. A functional diagram of the MAX3744/MAX3745 is shown in Figure 1. The MAX3744/MAX3745 comprise a transimpedance amplifier stage, a voltage amplifier stage, an output buffer, and a direct-current (DC) feedback cancellation circuit. The MAX3744 also includes a signal strength indicator (RSSI). To provide this signal in 6 a standard 4-pin TO header, the RSSI level is added to the common mode of the differential data output pins. Transimpedance Amplifier Stage The signal current at the input flows into the summing node of a high-gain amplifier. Shunt feedback through the resistor RF converts this current to a voltage. In parallel with the feedback resistor are two back-to-back Schottky diodes that clamp the output signal for large input currents, as shown in Figure 2. _______________________________________________________________________________________ 2.7Gbps SFP Transimpedance Amplifiers with RSSI MAX3744/MAX3745 AMPLITUDE AMPLITUDE INPUT FROM PHOTODIODE TIME OUTPUT (SMALL SIGNALS) OUTPUT (LARGE SIGNALS) TIME INPUT AFTER DC CANCELLATION Figure 2. MAX3744/MAX3745 Limited Output Figure 3. DC Cancellation Effect on Input VCC 100 Voltage Amplifier Stage The voltage amplifier stage provides gain and converts the single-ended input to differential outputs. DC Cancellation Circuit The DC cancellation circuit uses low-frequency feedback to remove the DC component of the input signal (Figure 3). This feature centers the input signal within the transimpedance amplifier's linear range, thereby reducing pulse-width distortion caused by large input signals. The DC cancellation circuit is internally compensated and therefore does not require external capacitors. OUT+ OUT- Output Buffer The output buffer provides a reverse-terminated voltage output. The buffer is designed to drive a 100 differential load between OUT+ and OUT-. The MAX3744 must be DC-coupled to the MAX3748A. See Figures 4 and 5. For optimum supply-noise rejection, the MAX3745 should be terminated with a matched load. If a singleended output is required, the unused output should be terminated to a 50 resistor to V CC. The MAX3745 does not drive a DC-coupled, 50 grounded load; however, it does drive a compatible 50 CML input. Figure 4. Equivalent Output MAX3744 VCC 50 50 OUT+ OUT- Signal-Strength Indicator The MAX3744 produces a signal proportional to the average photodiode current. This is added to the common mode of the data outputs OUT+ and OUT-. This signal is intended for use with the MAX3748A to provide a ground-referenced RSSI voltage. Applications Information Signal-Strength Indicator The SFF-8472 digital diagnostic specification requires monitoring of input receive power. The MAX3748A and MAX3744 receiver chipset allows for the monitoring of the average receive power by measuring the average DC current of the photodiode. Figure 5. Equivalent Output MAX3745 7 _______________________________________________________________________________________ 2.7Gbps SFP Transimpedance Amplifiers with RSSI The MAX3744 preamp measures the average photodiode current and provides the information to the output common mode. The MAX3748A RSSI detect block senses the common-mode DC level of input signals IN+ and IN- and provides a ground-level-referenced output signal of the photodiode current. The advantage of this implementation is that it allows the TIA to be packaged in a low-cost conventional 4-pin TO-46 header. The MAX3748A RSSI output is connected to an analog input channel of the DS1858/DS1859 SFP controller to convert the analog information into a 16-bit word. The DS1858/DS1859 provide the received power information to the host board of the optical receiver through a 2-wire interface. The DS1859 allows for internal calibration of the receive power monitor. The MAX3744 and the MAX3748A have been optimized to achieve RSSI stability of better than 2.5dB within the 6A to 500A range of average input photodiode current. To achieve the best accuracy, Maxim recommends receive power calibration at the low end (6A) and the high end (500A) of the required range. MAX3744/MAX3745 Optical Sensitivity Calculation The input-referred RMS noise current (I N ) of the MAX3744/MAX3745 generally determines the receiver sensitivity. To obtain a system bit-error rate (BER) of 1E-12, the signal-to-noise ratio must always exceed 14.1. The input sensitivity, expressed in average power, can be estimated as: 14.1 x IN (re + 1) 1000 dBm Sensitivity = 10log 2(re - 1) where is the photodiode responsivity in A/W and IN is RMS current in amps. Input Optical Overload The overload is the largest input that the MAX3744/ MAX3745 can accept while meeting deterministic jitter specifications. The optical overload can be estimated in terms of average power with the following equation: 2mARMS (re + 1) Overload = 10log 1000 dBm 2(re - 1) Optical Power Relations Many of the MAX3744/MAX3745 specifications relate to the input signal amplitude. When working with optical receivers, the input is sometimes expressed in terms of average optical power and extinction ratio. Figure 6 and Table 1 show relations that are helpful for converting optical power to input signal when designing with the MAX3744/MAX3745. (Refer to Application Note HFAN-3.0.0: Accurately Estimating Optical Receiver Sensitivity.) Optical Linear Range The MAX3744/MAX3745 have high gain, which limits the output when the input signal exceeds 50AP-P. The MAX3744/MAX3745 operate in a linear range (10% linearity) for inputs not exceeding: 50ARMS (re + 1) Linear Range = 10log 1000 dBm 2(re - 1) Table 1. Optical Power Relations PARAMETER Average power Extinction ratio Optical power of a 1 Optical power of a zero Signal amplitude SYMBOL PAVG re P1 P0 PIN PAVG = (P0 + P1) / 2 r e = P1 / P 0 P1 = 2PAVG(re) / (re + 1) P0 = 2PAVG / (re + 1) PIN = P1 - P0; PIN = 2PAVG(re - 1) / (re + 1) RELATION Note: Assuming 50% average duty cycle and mark density. 8 _______________________________________________________________________________________ 2.7Gbps SFP Transimpedance Amplifiers with RSSI Layout Considerations Noise performance and bandwidth are adversely affected by capacitance at the IN pad. Minimize capacitance on this pad and select a low-capacitance photodiode. Assembling the MAX3744/MAX3745 in die form using chip and wire technology provides the best possible performance. Figure 7 shows a suggested layout for a TO header for the MAX3744/MAX3745. The placement of the filter cap to minimize the ground loop of the photodiode is required to achieve the specified bandwidth. The OUT+ and OUT- bond wire lengths should also be minimized to meet the bandwidth specification. Special care should be taken to ensure that ESD at IN does not exceed 500V. Current generated by supply noise voltage is divided between CFILTER and CPD. The input noise current due to supply noise is (assuming the filter capacitor is much larger than the photodiode capacitance): INOISE = (VNOISE)(CPD) / (RFILTER)(CFILTER) If the amount of tolerable noise is known, the filter capacitor can be easily selected: CFILTER = (VNOISE)(CPD) / (RFILTER)(INOISE) For example, with maximum noise voltage = 100mVP-P, CPD = 0.85pF, RFILTER = 600, and INOISE selected to be 350nA: CFILTER = (100mV)(0.85pF) / (600)(350nA) = 405pF MAX3744/MAX3745 Photodiode Filter Supply voltage noise at the cathode of the photodiode produces a current I = CPD V/t, which reduces the receiver sensitivity (C PD is the photodiode capacitance.) The filter resistor of the MAX3744/MAX3745, combined with an external capacitor, can be used to reduce this noise (see the Typical Application Circuit). Wire Bonding For high-current density and reliable operation, the MAX3744/MAX3745 use gold metalization. Connections to the die should be made with gold wire only, using ballbonding techniques. Die thickness is typically 14 mils (0.4mm). TOP VIEW OF TO-46 HEADER PI CASE GROUND 400pF TO 1000pF 400pF TO 1000pF VCC OPTICAL POWER PAVG PHOTODIODE OUTOUT+ PO TIME MAX3744 MAX3745 Figure 6. Optical Power Relations Figure 7. Suggested Layout for TO-46 Header _______________________________________________________________________________________ 9 2.7Gbps SFP Transimpedance Amplifiers with RSSI MAX3744/MAX3745 Chip Topography GND MAX3744 MAX3745 VCC 1 10 9 OUT+ N.C. 2 3 4 5 6 7 8 OUT0.03in (0.76mm) VCC IN FILTER GND 0.05in (1.26mm) N.C. Pad Coordinates PAD 1 2 3 4 5 6 7 8 9 10 COORDINATES (m) X 1.4 0 0 0 0 494.2 865.2 1005.2 1005.2 490 COORDINATES (m) Y 495.6 336 224 112 0 -1.4 -1.4 -1.4 495.6 495.6 Chip Information TRANSISTOR COUNT: 301 PROCESS: SiGe Bipolar SUBSTRATE: ISOLATED DIE THICKNESS: 0.014in 0.001in Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time. 10 ____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 (c) 2003 Maxim Integrated Products Printed USA is a registered trademark of Maxim Integrated Products. |
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