19-3103; Rev 0; 12/07 Multirate CDR with Integrated Serializer/Deserializer for GPON and BPON ONT Applications Features The MAX3886 2.488Gbps/1.244Gbps/622Mbps CDR with SerDes (serializer/deserializer) is designed specifically for low-cost optical network terminal (ONT) applications in Gigabit passive optical network (GPON) and broadband passive optical network (BPON) fiber-tothe-home (FTTH) systems. It provides G.984- and G.983-compliant clock and data recovery (CDR) for the continuous downstream data signal, with an integrated 4-bit SerDes that has LVDS parallel interfaces and CML serial interfaces. The SerDes uses the recovered downstream clock for upstream serialization (loopback clock), providing optimum PON operation. The CDR frequency reference can be provided by a low-cost 19.44MHz SMD-type crystal or external LVCMOS source, and excellent jitter tolerance supports applications requiring FEC. An integrated burst-enable signal path also simplifies highperformance upstream burst timing. ♦ 2.488Gbps, 1.244Gbps, and 622Mbps Clock and Data Recovery ♦ Meets G.984 and G.983 Jitter Requirements ♦ 4-Bit Serializer and 4-Bit Deserializer with Loop-Timed Serialization ♦ CML Serial I/O, LVDS Parallel I/O ♦ Integrated Reference Oscillator Uses 19.44MHz SMD Crystal ♦ Integrated Upstream Burst-Enable Signal Path Ordering Information This 3.3V IC is housed in a 8mm x 8mm, 56-lead thin QFN package and operates from -40°C to +85°C. PART TEMP RANGE PINPACKAGE MAX3886ETN+ -40°C to +85°C 56 TQFN (8mm x 8mm) PKG CODE T5688-2 +Denotes a lead-free package. Applications Pin Configuration appears at end of data sheet. BPON/GPON Optical Network Terminal (ONT) Typical Application Circuit +3.3V +3.3V 0.27μF VCC CFIL RFCK1 MVCO MDDR MSYM 19.4400MHz 1490nm MAX3747/ 2.488G MAX3748 LIM AMP PON BiDi TRIPLEXER 1310nm MAX3643/ MAX3656 LD DRIVER RFCK2 SDI +3.3V VCC VOICE MAC IC SLIC MAX3886 PCKO PDO[3:0] PDI[3:0] 1.244G SDO PCKI BENO BENI GND LOCK FRST FERR GPON CDR/SERDES PCLK (311MHz) PDATA (622Mbps) PDATA (311Mbps) PCLK (311MHz) BURST ENABLE DATA 10/100 ETHERNET 1550nm 870MHz VIDEO MAX3654 VIDEO TIA GPON OPTICAL NETWORK TERMINAL (ONT) ________________________________________________________________ Maxim Integrated Products For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642, or visit Maxim’s website at www.maxim-ic.com. 1 MAX3886 General Description MAX3886 Multirate CDR with Integrated Serializer/Deserializer for GPON and BPON ONT Applications ABSOLUTE MAXIMUM RATINGS Supply Voltage Range (VCC).................................-0.3V to +4.0V CML Input Voltage Range (SDI±)...............-0.3V to (VCC + 0.3V) CML Output Current (SDO±, BENO±)...............................±22mA LVDS Input Voltage Range (PCKI±, PDI[3:0]±, BENI±)......................-0.3V to (VCC + 0.3V) LVDS Output Voltage Range (RCKO±, PDO[3:0]±, PCKO±) ................-0.3V to (VCC + 0.3V) LVCMOS Input Voltage Range (MSYM, MDDR, FRST)............................-0.3V to (VCC + 0.3V) Three-State Input Voltage Range (MVCO)...................................................-0.3V to (VCC + 0.3V) LVCMOS Output Voltage Range (LOCK, FERR) ........................................-0.3V to (VCC + 0.3V) Voltage Range at CFIL, RFCK1, RFCK2, TP1, TP2, TP3, TP4 ...................-0.3V to (VCC + 0.3V) Continuous Power Dissipation (TA = +70°C) 56-Pin TQFN (derate 47.6mW/°C above 70°C)..........3808mW Operating Junction Temperature Range ...........-55°C to +150°C Storage Temperature Range .............................-55°C to +150°C Lead Temperature (soldering, 10s) .................................+300°C 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. OPERATING CONDITIONS MAX UNITS Operating Temperature PARAMETER SYMBOL TA CONDITIONS MIN -40 +85 °C Power-Supply Voltage VCC 3.0 3.6 V Downstream/Upstream Data Rates Reference Frequency Internal or external oscillator Crystal Accuracy Includes aging, temperature, and other contributors Crystal ESR Fundamental type, AT-strip cut TYP See Table 2 Gbps 19.4400 MHz ±250 10 Crystal Drive Crystal Load Capacitance On-chip parallel capacitance Reference Clock Input Duty Cycle When driven by an LVCMOS clock source 60 100 μW 18 40 ppm pF 60 % ELECTRICAL CHARACTERISTICS (VCC = +3.0V to +3.6V, TA = -40°C to +85°C. Typical values are at VCC = +3.3V, TA= +25°C, unless otherwise noted. LVDS outputs terminated 100Ω differential, CML inputs terminated 100Ω differential, CML outputs terminated 100Ω differential.) (Note 1) PARAMETER Supply Current SYMBOL CONDITIONS MIN ICC TYP MAX UNITS 240 310 mA CDR/DESERIALIZER SPECIFICATIONS Serial Input Data Rate Rate SDI to SDO Jitter Transfer 2 2488.32 MVCO = open 1244.16 MVCO = 0 622.08 BER 10 -10 (Note 2) CDR CID Immunity CDR Sinusoidal Jitter Tolerance MVCO = 1 f > fC BER 10 -10 (Note 3) 0.3 Mbps > 100 Bits 0.7 UI P-P (Notes 4, 5) _______________________________________________________________________________________ 0.1 dB Multirate CDR with Integrated Serializer/Deserializer for GPON and BPON ONT Applications (VCC = +3.0V to +3.6V, TA = -40°C to +85°C. Typical values are at VCC = +3.3V, TA= +25°C, unless otherwise noted. LVDS outputs terminated 100Ω differential, CML inputs terminated 100Ω differential, CML outputs terminated 100Ω differential.) (Note 1) PARAMETER SYMBOL CONDITIONS SDI to SDO Jitter Transfer Bandwidth (Notes 3, 4) Parallel Clock Output Random Jitter (Note 6) Parallel-Output Clock to Data Time Parallel Clock and Data-Output Rise/Fall Time tCK-Q tr, t f Figure 1 MIN TYP UNITS fC MHz < 0.5 -80 20% to 80% Parallel-Clock Output Duty Cycle MAX 45 Parallel-Clock Output Frequency mUIRMS +80 ps 300 ps 55 % See Table 2 Parallel-Data Output Channel-to-Channel Skew MHz 100 CDR Acquisition Time (After Startup) Reference-Output Clock Frequency ps 2 ms See Table 2 MHz SERIALIZER SPECIFICATIONS Parallel-Input Clock Frequency See Table 2 MHz Serial-Output Data Rate See Table 2 Mbps Parallel-Data Input-Setup Time t SU Figure 1 170 ps Parallel-Data Input-Hold Time tHD Figure 1 300 ps Serial-Data Output Rise/Fall Time tr, t f 20% to 80% 160 ps Serial-Data Output Random Jitter (Notes 5, 6) 4 mUIRMS Serial-Data Output Deterministic Jitter (Notes 2, 5) 47 mUI P-P +50 ps Burst Enable to Serial Data MSB Time tB-MSB Figure 2 -50 Minimum Pulse Width of FIFO Reset UI is PCKO period 4 UI Tolerated Drift Between PCKI and PCKO After FIFO Reset UI is PCKO period ±1 UI I/O SPECIFICATIONS CML Differential Input Voltage CML Input Common-Mode Range VIN 200 VCC 1.49 VCC 1.32 1600 mVP-P VCC VIN/4 V _______________________________________________________________________________________ 3 MAX3886 ELECTRICAL CHARACTERISTICS (continued) MAX3886 Multirate CDR with Integrated Serializer/Deserializer for GPON and BPON ONT Applications ELECTRICAL CHARACTERISTICS (continued) (VCC = +3.0V to +3.6V, TA = -40°C to +85°C. Typical values are at VCC = +3.3V, TA= +25°C, unless otherwise noted. LVDS outputs terminated 100Ω differential, CML inputs terminated 100Ω differential, CML outputs terminated 100Ω differential.) (Note 1) MIN TYP MAX UNITS CML Differential Output PARAMETER SYMBOL 640 800 1000 mVP-P CML Differential Output Resistance 80 100 120 LVDS Input Voltage Range 0 2400 mV ±100 ±600 mV 120 1475 mV LVDS Differential Input Range CONDITIONS (Note 5) LVDS Differential Input Resistance 80 100 LVDS Output Voltage High LVDS Output Voltage Low 925 LVDS Output Differential Voltage VOD Figure 3 LVDS Output Offset Voltage VOS VOS = (VOUT+ + VOUT-)/2, Figure 3 LVDS Output Change in VOD |V OD | Between “0” and “1” LVDS Output Change in VOS |V OS | Between “0” and “1” LVDS Differential Output Resistance 400 1125 1275 mV 25 mV 25 mV 140 0.8 V 80 LVCMOS Input Voltage Low VIL LVCMOS Input Voltage High VIH mV 250 100 2.0 mV V LVCMOS Input Current VIH = VCC or VIL = ground -10 +10 μA Three-State Input Current MVCO input, VIH = VCC or VIL = ground I OL = 100μA -50 +50 μA 0.2 V LVCMOS Output Voltage Low LVCMOS Output Voltage High VOL VOH I OH = -100μA VCC 0.2 Note 1: With a 19.4400MHz SMD AT-strip crystal at RFCK1 and RFCK2. Note 2: Pattern is 16 x 27 - 1 PRBS, 100 CIDs, 16 x 27 - 1 PRBS inverted, 100 CIDs inverted. Note 3: For 622Mbps operation, fC = 500kHz. For 1.244Gbps operation, fC = 1MHz. For 2.488Gbps operation, fC = 2MHz. Note 4: Jitter transfer from SDI to SDO, with parallel side looped back. Defined as: ⎡ jitter on upstream signal UI downstream bit rate ⎤ × Jitter transfer = ⎢ ⎥ upstream bit rate ⎥⎦ ⎢⎣ jitter on downstream signal UI Note 5: Guaranteed by design and characterization. Note 6: For 2.488Gbps operation, measurement bandwidth = 8kHz to 20MHz. For 1.244Gbps operation, measurement bandwidth = 4kHz to 10MHz. For 622Mbps operation, measurement bandwidth = 2kHz to 5MHz. For 155Mbps operation, measurement bandwidth = 0.5kHz to 1.3MHz. 4 _______________________________________________________________________________________ V Multirate CDR with Integrated Serializer/Deserializer for GPON and BPON ONT Applications MAX3886 1UI SDO PDI1 PDI0 PDI3 PDI2 PDI1 PDO_ PCKO (MDDR = 0) BENO tB-MSB MIN tB-MSB MAX PCKO (MDDR = 1) Figure 2. Burst-Enable Timing tCK-Q MAX tCK-Q MIN 1UI PDI_ PCKI tSU tHD Figure 1. Parallel Interface Timing Diagrams LVDS RL = 100Ω V VOD VOUTSINGLE- ENDED OUTPUT VOD VOS VOUT+ +VOD DIFFERENTIAL OUTPUT VOD(P-P) = VOUT+ - VOUT- 0V -VOD Figure 3. Definition of LVDS Output Levels _______________________________________________________________________________________ 5 Typical Operating Characteristics (VCC = 3.3V, TA = +25°C, unless otherwise noted.) 622Mbps PARALLEL DATA AND CLOCK OUTPUT (MVCO = 1, MDDR = 0) 622Mbps PARALLEL DATA AND CLOCK OUTPUT (MVCO = 1, MDDR = 1) MAX3886 toc02 MAX3886 toc03 200mV/div 200mV/div 100mV/div MAX3886 toc01 120ps/div 1 G.984 MASK 0.01 10 1 0.1 G.984 MASK 0.01 10k 100k 1M 10M TOLERANCE EXCEEDS TEST EQUIPMENT GENERATION LIMIT 10 1 0.1 0.01 10k 100k 1M 10M 10k 100k 1M 10M JITTER FREQUENCY (Hz) JITTER FREQUENCY (Hz) SDI TO SDO JITTER TRANSFER (SDI = 2.488Gbps) SDI TO SDO JITTER TRANSFER (SDI = 1.244Gbps) SDI TO SDO JITTER TRANSFER (SDI = 622Mbps) -3 -4 G.984 MASK -5 -6 -7 -2 -3 -4 -5 G.984 MASK -6 -7 0 -1 -2 -3 -4 -5 -6 -8 -9 -9 -9 -10 -10 -10 100k 1M JITTER FREQUENCY (Hz) 10M G.984 MASK G.983 -7 -8 10k MAX3886 toc09 -1 JITTER TRANSFER (dB) -2 0 JITTER TRANSFER (dB) -1 1 MAX3886 toc08 1 MAX3886 toc07 0 1k G.984 MASK G.983 JITTER FREQUENCY (Hz) 1 6 TOLERANCE EXCEEDS TEST EQUIPMENT GENERATION LIMIT 622Mbps JITTER TOLERANCE 100 SINUSOIDAL JITTER TOLERANCE (UIP-P) 10 SINUSOIDAL JITTER TOLERANCE (UIP-P) SINUSOIDAL JITTER TOLERANCE (UIP-P) TOLERANCE EXCEEDS TEST EQUIPMENT GENERATION LIMIT 100 MAX3886 toc05 1.244Gbps JITTER TOLERANCE MAX3886 toc04 2.488Gbps JITTER TOLERANCE 100 0.1 500ps/div 500ps/div MAX3886 toc06 1.244Gbps SERIAL DATA OUTPUT (MVCO = 1, MSYM = 0) JITTER TRANSFER (dB) MAX3886 Multirate CDR with Integrated Serializer/Deserializer for GPON and BPON ONT Applications -8 1k 10k 100k 1M JITTER FREQUENCY (Hz) 10M 1k 10k 100k 1M JITTER FREQUENCY (Hz) _______________________________________________________________________________________ 10M Multirate CDR with Integrated Serializer/Deserializer for GPON and BPON ONT Applications 0.6 SDI = 622Mbps 622Gbps BW = 2kHz TO 5MHz 0.5 0.4 0.3 0.2 3.0 2.5 1.0 0.5 0.0 0.0 -15 10 35 60 85 SDO SDI = 622Gbps 622Mbps BW = 2kHz TO 5MHz 1.5 0.1 -40 SDO SDI == 1.244Gbps 1.244Gbps BW = 4kHz TO 10MHz 2.0 2.0 SDO SDI == 2.488Gbps 1.244Gbps BW = 4kHz 8kHz TO 10MHz 20MHz 1.8 RANDOM JITTER (mUIRMS) SDI = 1.244Gbps BW = 4kHz TO 10MHz 0.7 SDO SDI == 2.488Gbps 2.488Gbps BW = 8kHz TO 20MHz 3.5 RANDOM JITTER (mUIRMS) RANDOM JITTER (mUIRMS) 0.8 4.0 MAX3886 toc11 SDI = 2.488Gbps BW = 8kHz TO 20MHz 0.9 MAX3886 toc10 1.0 SDO RANDOM JITTER vs. TEMPERATURE (ASYMMETRIC, MSYM = 0) SDO RANDOM JITTER vs. TEMPERATURE (SYMMETRIC, MSYM = 1) 1.6 SDI SDO==1.244Gbps 622Mbps BW BW==4kHz 2kHzTO TO10MHz 5MHz 1.4 1.2 1.0 MAX3886 toc12 PARALLEL CLOCK OUTPUT RANDOM JITTER vs. TEMPERATURE SDO SDI = 622Gbps 155Mbps BW BW= =0.5kHz 2kHz TO 5MHz 1.3MHz 0.8 0.6 0.4 0.2 0.0 -40 TEMPERATURE (°C) -15 10 35 60 85 TEMPERATURE (°C) -40 -15 10 35 60 85 TEMPERATURE (°C) Pin Description PIN NAME FUNCTION 1, 14, 15, 29, 42, 43, 56 GND Supply Ground 2 TP1 Test Pin, Reserved. Connect to GND for normal operation. 3, 6, 12, 28, 46, 53 VCC +3.3V Supply Voltage 4 SDI+ Positive Serial Data Input, CML or LVPECL 5 SDI- Negative Serial Data Input, CML or LVPECL 7 BENO- Negative Burst-Enable Output, CML 8 BENO+ Positive Burst-Enable Output, CML 9 TP2 10 SDO- Test Pin, Reserved. Connect to VCC for normal operation. 11 SDO+ 13 TP3 16 PCKI+ Positive Parallel Clock Input, LVDS 17 PCKI- Negative Parallel Clock Input, LVDS 18 PDI3+ Positive Parallel Data Input 3, LVDS, MSB (First Serial Bit Out) 19 PDI3- Negative Parallel Data Input 3, LVDS, MSB (First Serial Bit Out) 20 PDI2+ Positive Parallel Data Input 2, LVDS 21 PDI2- Negative Parallel Data Input 2, LVDS 22 PDI1+ Positive Parallel Data Input 1, LVDS Negative Serial Data Output, CML Positive Serial Data Output, CML Test Pin, Reserved. Connect to GND for normal operation. _______________________________________________________________________________________ 7 MAX3886 Typical Operating Characteristics (continued) (VCC = 3.3V, TA = +25°C, unless otherwise noted.) Multirate CDR with Integrated Serializer/Deserializer for GPON and BPON ONT Applications MAX3886 Pin Description (continued) 8 PIN NAME 23 PDI1- Negative Parallel Data Input 1, LVDS FUNCTION 24 PDI0+ Positive Parallel Data Input 0, LVDS, LSB (Last Serial Bit Out) 25 PDI0- Negative Parallel Data Input 0, LVDS, LSB (Last Serial Bit Out) 26 BENI+ Positive Burst Enable Input, LVDS 27 BENI- Negative Burst Enable Input, LVDS 30 RCKO+ Positive Parallel Rate Reference Clock Output, LVDS 31 RCKO- Negative Parallel Rate Reference Clock Output, LVDS 32 PDO3+ Positive Parallel Data Output 3, LVDS, MSB (First Serial Bit In) 33 PDO3- Negative Parallel Data Output 3, LVDS, MSB (First Serial Bit In) 34 PDO2+ Positive Parallel Data Output 2, LVDS 35 PDO2- Negative Parallel Data Output 2, LVDS 36 PDO1+ Positive Parallel Data Output 1, LVDS 37 PDO1- Negative Parallel Data Output 1, LVDS 38 PDO0+ Positive Parallel Data Output 0, LVDS, LSB (Last Serial Bit In) 39 PDO0- Negative Parallel Data Output 0, LVDS, LSB (Last Serial Bit In) 40 PCKO+ Positive Parallel Clock Output, LVDS; Rate/4 or Rate/8, depending on value of MDDR pin. See Figure 1 for timing diagram. 41 PCKO- Negative Parallel Clock Output, LVDS; Rate/4 or Rate/8, depending on value of MDDR pin. See Figure 1 for timing diagram. 44 FERR FIFO Error Output, LVCMOS. A high output indicates when the FIFO read and write clocks attempt to access the same register. Normally connected to MAC IC. 45 FRST FIFO Reset Input, LVCMOS. A high input resets the FIFO. Normally connected to MAC IC. 47 RFCK2 48 RFCK1 Reference Clock Crystal Input. See Pin 47. 49 MDDR Dual Data Rate Select Input, LVCMOS. A high input selects dual data rate (DDR) parallel clock output. See Figure 1 for timing diagram. 50 MSYM Symmetric Select Input, LVCMOS. A high input selects symmetric operation, a low input selects asymmetric operation. See Table 2. 51 MVCO VCO Rate Select Input, Three-State. See Table 2. 52 LOCK PLL Lock Detector Output, LVCMOS. A high output indicates the PLL is in lock, this output can chatter when no valid input signal is present. 54 CFIL PLL Filter Capacitor Connection. Connect a 0.27μF ceramic capacitor (±10%, 10V, X7R-type) between pin 54 and pin 53. 55 TP4 Test Pin, Reserved. Connect to VCC for normal operation. — EP Exposed Paddle. Connect to thermal and electrical ground. Reference Clock Crystal Input. A 19.4400MHz crystal must be connected between RFCK1 and RFCK2; or a 19.4400MHz LVCMOS clock source (capable of driving up to 10pF load) can be connected through a 10pF ±10% series capacitor to RFCK1, RFCK2 unconnected. _______________________________________________________________________________________ Multirate CDR with Integrated Serializer/Deserializer for GPON and BPON ONT Applications The MAX3886 CDR/SerDes provides 2.488Gbps/ 1.244Gbps/622Mbps clock and data recovery, plus 1:4 deserializer for continuous downstream data and 1:4 serializer for burst upstream data (Figure 4). Specifically designed for GPON and BPON ONT applications, the serializer uses the recovered downstream clock to serialize the upstream serial data (loop-timed serialization). The upstream rate can be configured to be either equal to the downstream rate (symmetric operation) or a submultiple of the downstream rate (asymmetric operation). A low-cost 19.4400MHz SMDtype crystal or external LVCMOS source serves as the CDR frequency reference, providing robust frequency acquisition and lock detection. A parallel rate reference clock output, derived from the recovered downstream signal, is provided for use by the MAC layer IC, and an integrated FIFO is provided to deal with phase variation between the serializer and MAC layer IC. Once the FIFO has been initialized, the serializer tolerates up to one parallel UI phase difference between the read and write clocks. The FIFO circuitry includes an error output that indicates when the FIFO attempts to read and write from the same location. An integrated burst-enable signal path also includes the FIFO to simplify upstream burst timing. The deserializer parallel output clock can optionally be configured for dual data rate (DDR) operation. The high-speed CML-format serial-data interfaces are compatible with Maxim burst-mode laser drivers and both CML and LVPECL limiting amplifiers. The parallel data interfaces are LVDS format for compatibility with FPGAs or ASICs. Serial Input Clock/Data Recovery Clock and data recovery is provided by a phase-locked loop (PLL) with selectable 2.488GHz/1.244GHz/ 622MHz operation. The operating frequency is controlled by the three-state MVCO input. A phase detector and filter generate error voltage proportional to the phase difference between the internal VCO and the input data, and feedback in the PLL drives the error voltage to zero, aligning the recovered clock to the center of the input data for retiming. A frequency detector assists the PLL to “pull in” to the serial data and generates the lock indicator signal on the LOCK pin. When no valid input signal is present, the LOCK output can oscillate (chatter) as the PLL hunts for the input signal. The PLL VCO and integrated loop filter implement a second-order transfer function, with loop bandwidth dependent on the VCO rate selected (e.g., 1.5MHz for 2.488Gbps). An external filter capacitor, connected between CFIL and VCC sets the damping factor of the PLL. All jitter specifications are based on an external 0.27µF capacitor. Modifying the value of CFIL changes jitter peaking, acquisition time, and loop stability but not loop bandwidth. PLL Reference Clock Oscillator An integrated oscillator provides a reference clock signal for robust CDR acquisition and lock detection. This oscillator requires a 19.4400MHz crystal connected between RFCK1 and RFCK2, or an external LVCMOS 19.4400MHz clock source can be used. See the Applications Information section for important information about crystal selection and how to connect an external clock source. Deserializer and Parallel Output The downstream data is deserialized, producing four parallel LVDS outputs, PDO[3:0]±. The first serial data bit received on the SDI input is the most significant bit (MSB), which is routed to the parallel output PDO3. The LVDS parallel output clock, PCKO, can be configured for either full rate or half rate operation, as shown in the timing diagrams of Figure 1. The PCKO rate is controlled using the LVCMOS MDDR input. Set the MDDR pin to logic high to clock out parallel data on each edge of the PCKO clock. Parallel Input, FIFO, and Serializer Parallel data presented at the four LVDS data inputs PDI[3:0]± is latched into the input register using the LVDS parallel input clock PCKI and clocked out of the ONT SerDes using the recovered serial clock. The parallel data bit PDI3 is the MSB and the first bit out of the serial SDO output. For GPON and BPON ONT applications, the clock multiplier unit (CMU) frequency synthesizer normally incorporated in SONET serializers is eliminated, improving PON performance. Asymmetric operation is configured using the LVCMOS MSYM input (see Table 2). The parallel clock is also output on the LVDS RCKO pins for use, if needed, by the MAC layer. The serializer’s 4-bit-long FIFO accommodates phase variation between RCKO and PCKI. PCKI provides the FIFO write clock and the internal RCKO is the read clock (loading the 4:1 serializer); this arrangement allows the phase relationship between these two clocks to vary ±1UI. In the event that valid read and write clocks attempt to access the same FIFO address, this error condition is indicated on the LVCMOS FERR output. To initiate the FIFO or clear an error condition, the LVCMOS FRST input must be asserted high for at least 4UI while valid clocks are present. _______________________________________________________________________________________ 9 MAX3886 Detailed Description MAX3886 Multirate CDR with Integrated Serializer/Deserializer for GPON and BPON ONT Applications CFIL PDO3+ Q D LVDS PDO3- SDI+ PDO2+ PD CML LPF VCO Q CLK SDI- LVDS PDO2- 4-BIT SERIAL TO PARALLEL LOCK CDR PLL CMOS PDO1+ Q LVDS PDO1- FREQ DETECT RFCK1 OSC PDO0+ Q RFCK2 CLK/4 PDO0PCKO+ 1 DIV 2 MVCO LVDS CMOS LVDS 0 PCKO- 1 0 DIV 2, DIV 4 DIV 4 CMOS MDDR CMOS MSYM PCKI+ RCKO+ LVDS LVDS RCKO- PCKIPDI3+ CLK D RD WR CLK LVDS PDI3PDI2+ D LVDS PDI2- CLK SDO+ CML Q D Q PDI1+ SDOD 4-BIT PARALLEL TO SERIAL D 5 x 4 FIFO REGISTER LVDS PDI1PDI0+ LVDS PDI0BENI+ CLK BENO+ CML Q D LVDS BENO- BENICMOS MAX3886 CMOS FERR FRST Figure 4. Functional Diagram 10 ______________________________________________________________________________________ Multirate CDR with Integrated Serializer/Deserializer for GPON and BPON ONT Applications Lock Detector Output The lock detector operates by comparing a divideddown version of the VCO output to the reference clock. The LOCK output pin indicates lock (high) when the frequency difference between the reference clock and the CDR VCO is less than 250ppm, within the “pullin” range of the PLL. The LOCK output indicates out-of-lock (low) when the frequency difference between the reference clock and the CDR VCO becomes more than 500ppm. When valid input data is present, this provides a stable lock indication. At power-up, the CDR takes approximately 50ms (if valid NRZ data is present) for initial acquisition while the internal reference oscillator, the PLL, and the frequency detector reach their operating conditions. During this startup period, the LOCK status output may provide false indication of a lock condition. Once the PLL and frequency detector are initialized, the nominal time for reacquisition of an NRZ input is 2ms. When valid NRZ input data is not present, the lock detector may produce a chattering LOCK indicator output while the PLL searches for the input frequency. If needed, an external digital filter can be used to mask this chattering. Table 1. Lock Detector Output CDR INPUT LOCK OUTPUT Valid NRZ data 1 No CDR input 0/1 (chatter) Control Input Summary Table 2 summarizes the clock and data rates as controlled by MVCO, MSYM, and MDDR. Table 2. Clock and Data Rate Controls Rx MVCO MSYM 0 0 Tx MDDR SDI RATE (Mbps) PDO RATE (Mbps) PCKO (MHz) SDO RATE (Mbps) PDI RATE (Mbps) PCKI (MHz) RCKO (MHz) 0 0 622 155 155 155 39 39 39 0 1 622 155 78 155 39 39 39 0 1 0 622 155 155 622 155 155 155 0 1 1 622 155 78 622 155 155 155 Open 0 0 1244 311 311 622 155 155 155 Open 0 1 1244 311 155 622 155 155 155 Open 1 0 1244 311 311 1244 311 311 311 Open 1 1 1244 311 155 1244 311 311 311 1 0 0 2488 622 622 1244 311 311 311 1 0 1 2488 622 311 1244 311 311 311 1 1 0 2488 622 622 2488 622 622 622 1 1 1 2488 622 311 2488 622 622 622 ______________________________________________________________________________________ 11 MAX3886 Burst-Enable Signal Processing To minimize PON overhead, it is important that the laser driver burst-enable (BEN) signal correspond accurately with the beginning of the serial data burst. This is supported in the MAX3886 by the BENI LVDS input and associated signal path. The LVDS burst-enable signal from the MAC layer IC is passed through the same FIFO as the parallel data and output on the BENO CML output, which ensures that the laser driver’s burst enable matches the beginning of the associated serial MSB. If FRST or FERR are high, the BENO output is forced low to prevent the laser driver from transmitting erroneous data. The parallel data setup and hold timing requirements also apply to the burst-enable signal. MAX3886 Multirate CDR with Integrated Serializer/Deserializer for GPON and BPON ONT Applications Applications Information VCC Interfacing to the CDR/SerDes The MAX3886 has CML, LVDS, and LVCMOS inputs and outputs. The high-speed CML (LVPECL-compatible) inputs, SDI±, are biased to VCC - 1.3V with an onchip high-impedance network (Figure 5). Figures 6 and 7 provide examples of DC-coupled and AC-coupled termination networks that can be used to connect the limiting amplifier outputs (CML or LVPECL) to the SDI± inputs. The two high-speed CML outputs, SDO± and BENO±, have internal 50Ω back terminations to VCC (Figure 8) and should be terminated with 50Ω to VCC or 100Ω differential at the laser driver inputs (Figure 9). The burst SDO and BENO outputs must be DC-coupled to the laser driver for proper operation. SDO can be AC-coupled if a continuous serial signal is provided between bursts (with gating provided by the laser driver BEN input). The LVDS outputs (PDO[3:0]±, PCKO±, RCKO±) require 100Ω differential termination for proper operation. The LVDS inputs (PDI[3:0]±, PCKI±) are internally terminated with 100Ω differential resistance, eliminating the need for external termination when connected to an LVDS output (Figure 10). Equivalent circuits for the three-state input (MVCO), LVCMOS inputs (MSYM, MDDR, FRST), and LVCMOS VCC VCC 16kΩ 5kΩ SDI+ VCC 5kΩ SDI- 24kΩ MAX3886 Figure 5. CML (LVPECL-Compatible) Input outputs (LOCK, FERR) are given in Figure 11, Figure 12, and Figure 13. For more information on interfacing to Maxim’s high-speed I/O circuits, refer to Application Note HFAN-01.0: Introduction to LVDS, PECL, and CML. DC-COUPLED LIMITING AMPLIFIER Z0 = 50Ω SDI+ 100Ω CML Z0 = 50Ω MAX3886 SDI- AC-COUPLED LIMITING AMPLIFIER 0.1μF Z0 = 50Ω SDI+ 100Ω CML MAX3886 0.1μF Z0 = 50Ω SDI- Figure 6. Interface to Limiting Amplifier (CML Outputs) 12 ______________________________________________________________________________________ Multirate CDR with Integrated Serializer/Deserializer for GPON and BPON ONT Applications MAX3886 VCC DC-COUPLED 130Ω LIMITING AMPLIFIER 130Ω Z0 = 50Ω SDI+ LVPECL MAX3886 Z0 = 50Ω SDI82Ω 82Ω AC-COUPLED LIMITING AMPLIFIER 0.1μF Z0 = 50Ω SDI+ 100Ω LVPECL MAX3886 0.1μF Z0 = 50Ω 143Ω SDI- 143Ω Figure 7. Interface to Limiting Amplifier (LVPECL Outputs) VCC 50Ω MAX3886 50Ω SDO+/BENO+ SDO-/BENO- Figure 8. CML Outputs ______________________________________________________________________________________ 13 MAX3886 Multirate CDR with Integrated Serializer/Deserializer for GPON and BPON ONT Applications Z0 = 50Ω SDO+ CML IN+ 100Ω Z0 = 50Ω SDO- IN- MAX3886 MAX3656/MAX3643 CDR/SerDes BURST-MODE LASER DRIVER Z0 = 50Ω BENO+ BEN+ 100Ω CML Z0 = 50Ω BENO- BEN- Figure 9. Interface to Laser Driver MAC IC MAX3886 Z0 = 50Ω LVDS 100Ω 100Ω LVDS Z0 = 50Ω Z0 = 50Ω LVDS 100Ω 100Ω LVDS Z0 = 50Ω Figure 10. LVDS Interface 14 ______________________________________________________________________________________ Multirate CDR with Integrated Serializer/Deserializer for GPON and BPON ONT Applications VCC VCC P MVCO N MAX3886 Reference Clock Oscillator Figure 11. Three-State Input (MVCO) VCC The integrated reference oscillator requires a parallel resonant 19.4400MHz AT-strip cut crystal connected between pins RFCK1 and RFCK2. It has 18pF nominal (15pF to 21pF) of on-chip crystal load capacitance; any frequency error due to mismatch to the rated crystal load capacitance must be included in the budget for the difference between reference clock frequency and input data rate. Take care that the wiring capacitances at the nodes RFCK1 and RFCK2 are controlled (typically no more than 2pF) to ensure proper operation. VCC P MSYM MDDR FRST N To drive the reference clock with an external 19.4400MHz LVCMOS clock source, connect it to RFCK1 through a 10pF ±10% series capacitor and leave RFCK2 open. The LVCMOS clock source must be capable of driving a 10pF load. MAX3886 To ensure proper acquisition, the maximum difference between the downstream data rate (divided down to 19.4400MHz) and 19.4400MHz clock should be 500ppm, including 57ppm required by the CDR itself. Table 3 shows a typical budget. Figure 12. LVCMOS Inputs VCC VCC Table 3. Typical Frequency Budget P LOCK FERR N MAX3886 Figure 13. LVCMOS Outputs f (±ppm) DESCRIPTION NOTES Downstream Data Rate 50 G.983, G.984 Crystal Load Capacitance 63 e.g., 21ppm/pF from 18pF Crystal Tolerance 75 Crystal Temperature Stability 100 Crystal Aging 50 CDR Operation 57 Total 395 Total is less than 500ppm ______________________________________________________________________________________ 15 MAX3886 FIFO Control Signals A valid input at FRST is required to initialize the FIFO after the relationship between PCKO or RCKO and PCKI has stabilized prior to operating the serializer, or after the FERR output has indicated that the FIFO has overflowed or underflowed due to the phase difference between PCKO or RCKO and PCKI exceeding its capacity. The MAC IC provides the control signal for FRST. FERR should not be directly connected to FRST. If the PCKI signal is interrupted between bursts, the FIFO must be reset before the beginning of each burst while valid clocks are present. If a continuous PCKI signal is provided between bursts, the FIFO maintains the correct FIFO counter values as long as the phase relationship does not change. Power Supply and Ground Connection The 56-pin TQFN package features an exposed pad (EP) that provides a low resistance thermal path for heat removal from the IC and must be connected to the circuit board ground plane for proper operation. The EP also provides essential electrical ground connectivity. The MAX3886 has six VCC connection pads, and installation of a bypass capacitor at each VCC pad is recommended. All six VCC connections should be driven from the same source to eliminate the possibility of independent power-supply sequencing. Pin 53 provides current directly to the internal VCO stage; excessive supply noise at this node can result in increased jitter. Pin Configuration GND RCKO+ RCKO- PDO3+ PDO3- PDO2+ PDO2- PDO1+ PDO1- PDO0+ PDO0- PCKO+ PCKO- GND TOP VIEW 42 41 40 39 38 37 36 35 34 33 32 31 30 29 GND 43 28 VCC FERR 44 27 BENI- FRST 45 26 BENI+ VCC 46 25 PDI0- RFCK2 47 24 PDI0+ RFCK1 48 23 PDI122 PDI1+ MDDR 49 MAX3886 MSYM 50 21 PDI2- MVCO 51 20 PDI2+ LOCK 52 19 PDI3- VCC 53 18 PDI3+ 17 PCKI- CFIL 54 TP4 55 EP* + 16 PCKI+ 15 GND SDI- VCC 9 10 11 12 13 14 TP3 SDI+ 8 GND VCC 7 VCC 6 SDO+ 5 SDO- 4 TP2 3 BENO- 2 BENO+ 1 TP1 GND 56 GND MAX3886 Multirate CDR with Integrated Serializer/Deserializer for GPON and BPON ONT Applications THIN QFN (8mm × 8mm × 0.8mm) * THE EXPOSED PAD OF THE THIN QFN PACKAGE MUST BE SOLDERED TO GROUND FOR PROPER THERMAL AND ELECTRICAL OPERATION. 16 ______________________________________________________________________________________ Multirate CDR with Integrated Serializer/Deserializer for GPON and BPON ONT Applications TRANSISTOR COUNT: 10,684 PROCESS: SiGe BiCMOS Package Information (For the latest package outline information, go to www.maxim-ic.com/packages.) PACKAGE TYPE DOCUMENT NO. 56 Thin QFN 21-0135 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. Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 ____________________ 17 © 2007 Maxim Integrated Products is a registered trademark of Maxim Integrated Products, Inc. MAX3886 Chip Information