19-4911; Rev 0; 10/09 TION KIT EVALUA BLE IL AVA A Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs The MAX3639 is a highly flexible, precision phaselocked loop (PLL) clock generator optimized for the next generation of network equipment that demands low-jitter clock generation and distribution for robust high-speed data transmission. The device features subpicosecond jitter generation, excellent power-supply noise rejection, and pin-programmable LVDS/LVPECL output interfaces. The MAX3639 provides nine differential outputs and one LVCMOS output, divided into three banks. The frequency and output interface of each output bank can be individually programmed, making this device an ideal replacement for multiple crystal oscillators and clock distribution ICs on a system board, saving cost and space. This 3.3V IC is available in a 7mm x 7mm, 48-pin TQFN package and operates from -40°C to +85°C. Applications Ethernet Switch/Router Features S Inputs Crystal Interface: 18MHz to 33.5MHz LVCMOS Input: 15MHz to 160MHz Differential Input: 15MHz to 350MHz S Outputs LVCMOS Output: Up to 160MHz LVPECL/LVDS Outputs: Up to 800MHz S Three Individual Output Banks Pin-Programmable Dividers Pin-Programmable Output Interface S Wide VCO Tuning Range (3.60GHz to 4.025GHz) S Low Phase Jitter 0.34psRMS (12kHz to 20MHz) 0.14psRMS (1.875MHz to 20MHz) S Excellent Power-Supply Noise Rejection S -40NC to +85NC Operating Temperature Range S +3.3V Supply Ordering Information Wireless Base Station PCIeM, Network Processors SONET/SDH Line Cards Fibre Channel SAN Typical Application Circuits and Pin Configuration appear at end of data sheet. PART TEMP RANGE PIN-PACKAGE MAX3639ETM+ -40NC to +85NC 48 TQFN-EP* +Denotes a lead(Pb)-free/RoHS-compliant package. *EP = Exposed pad. Functional Diagram LVPECL/LVDS QA0 QA0 LVPECL/LVDS MAX3639 QA1 QA1 LVPECL/LVDS QA2 QA2 XOUT LVPECL/LVDS XO QA3 XIN LVPECL/LVDS LVCMOS CIN QA3 QA4 PLL, DIVIDERS, MUXES VCO QA4 LVPECL/LVDS QB0 QB0 LVPECL LVPECL/LVDS DIN DIN QB1 QB1 LVPECL/LVDS QB2 QB2 LVPECL/LVDS QC QC LVCMOS QCC PCIe is a registered trademark of PCI-SIG Corp. ________________________________________________________________ Maxim Integrated Products 1 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. MAX3639 General Description MAX3639 Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs ABSOLUTE MAXIMUM RATINGS Supply Voltage Range (VCC, VCCA, VCCQA, VCCQB, VCCQC, VCCQCC).................................-0.3V to +4.0V Voltage Range at CIN, IN_SEL, DM, DF[1:0], DP[1:0], PLL_BP, DA[1:0], DB[1:0], DC[1:0], QA_CTRL1, QA_CTRL2, QB_CTRL, QC_CTRL, QCC..................................... -0.3V to (VCC + 0.3V) Voltage Range at DIN, DIN......... (VCC - 2.35V) to (VCC - 0.35V) Voltage Range at QA[4:0], QA[4:0], QB[2:0], QB[2:0], QC, QC when LVDS Output.... -0.3V to (VCC + 0.3V) Current into QA[4:0], QA[4:0], QB[2:0], QB[2:0], QC, QC when LVPECL Output...................................... -56mA Current into QCC.............................................................. Q50mA Voltage Range at XIN............................................-0.3V to +1.2V Voltage Range at XOUT..............................-0.3V to (VCC - 0.6V) Continuous Power Dissipation (TA = +70NC) 48-Pin TQFN (derate 40mW/NC above +70NC)...........3200mW Operating Junction Temperature Range.......... -55NC to +150NC Storage Temperature Range............................. -65NC to +160NC 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 = +3.0V to +3.6V, TA = -40°C to +85°C. Typical values are at VCC = +3.3V, TA = +25°C, unless otherwise noted. Signal applied to CIN or DIN/DIN only when selected as the reference clock.) (Note 1) PARAMETER Supply Current with PLL Enabled (Note 2) SYMBOL ICC Supply Current with PLL Bypassed (Note 2) TYP MAX Configured with LVPECL outputs CONDITIONS MIN 170 215 Configured with LVDS outputs 290 365 Configured with LVPECL outputs 110 Configured with LVDS outputs 230 UNITS mA mA LVCMOS/LVTTL CONTROL INPUTS (IN_SEL, DM, DF[1:0], DA[1:0], DB[1:0], DC[1:0], PLL_BP, DP[1:0], QA_CTRL1, QA_CTRL2, QB_CTRL, QC_CTRL) Input High Voltage VIH 2.0 Input Low Voltage VIL Input High Current IIH VIN = VCC Input Low Current IIL VIN = 0V V 0.8 V 80 FA -80 FA LVCMOS/LVTTL CLOCK INPUT (CIN) Reference Clock Input Frequency fREF Input Amplitude Range Internally AC-coupled (Note 3) Input High Current IIH VIN = VCC Input Low Current IIL VIN = 0V Reference Clock Input Duty Cycle 15 160 MHz 1.2 3.6 VP-P 80 FA -80 40 Input Capacitance Input Differential Voltage Swing VCMI 15 VCC 1.8 % pF 350 VCC 1.3 MHz V 150 1800 mVP-P Single-Ended Voltage Range VCC 2.0 VCC 0.7 V Input Differential Impedance 80 Differential Input Capacitance 2 60 1.5 DIFFERENTIAL CLOCK INPUT (DIN, DIN) (Note 4) Differential Input Frequency fREF Input Bias Voltage FA 100 1.5 120 I pF Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs (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. Signal applied to CIN or DIN/DIN only when selected as the reference clock.) (Note 1) PARAMETER SYMBOL CONDITIONS MIN TYP LVDS OUTPUTS (QA[4:0], QA[4:0], QB[2:0], QB[2:0], QC, QC) (Note 5) Output Frequency Output High Voltage VOH Output Low Voltage VOL 0.925 Differential Output Voltage |VOD| 250 Change in Magnitude of Differential Output for Complementary States Output Offset Voltage Change in Magnitude of Output Offset Voltage for Complementary States 1.125 D|VOS| Differential Output Impedance 80 Output Current Output Current When Disabled 3 Short to ground 6 PLL enabled Output Duty-Cycle Distortion 100 Short together 800 MHz 1.475 V 400 mV 25 mV 1.3 V 25 mV 140 I mA 10 VQ__ = VQ__= 0V to VCC 20% to 80% Output Rise/Fall Time UNITS V D|VOD| VOS MAX 48 PLL bypassed (Note 6) FA 160 240 50 52 50 LVPECL OUTPUTS (QA[4:0], QA[4:0], QB[2:0], QB[2:0], QC, QC) (Note 7) Output Frequency ps % 800 MHz Output High Voltage VOH VCC 1.13 VCC 0.98 VCC 0.83 V Output Low Voltage VOL VCC 1.85 VCC 1.70 VCC 1.55 V 0.5 0.7 0.9 VP-P Output-Voltage Swing (Single-Ended) Output Current When Disabled Output Rise/Fall Time Output Duty-Cycle Distortion 10 VQ__ = VQ__ = 0V to VCC 20% to 80% PLL enabled 48 PLL bypassed (Note 6) FA 140 240 50 52 50 ps % LVCMOS/LVTTL OUTPUT (QCC) Output Frequency 160 MHz V IOH = -12mA Output Low Voltage IOL = 12mA 0.4 V Output Rise/Fall Time 20% to 80% (Note 8) 150 400 850 ps PLL enabled 42 50 58 Output Duty-Cycle Distortion Output Impedance PLL bypassed (Note 6) 2.6 VCC Output High Voltage 50 15 % I 3 MAX3639 ELECTRICAL CHARACTERISTICS (continued) MAX3639 Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs 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. Signal applied to CIN or DIN/DIN only when selected as the reference clock.) (Note 1) PARAMETER SYMBOL CONDITIONS MIN TYP MAX Low VCO (DP1 = 0 or NC) 3600 3750 3830 High VCO (DP1 = 1) 3830 3932 4025 UNITS PLL SPECIFICATIONS VCO Frequency Range fVCO Phase-Frequency Detector Compare Frequency fPFD 15 PLL Jitter Transfer Bandwidth Integrated Phase Jitter 130 RJ 25MHz crystal input (Note 9) 12kHz to 20MHz 0.34 1.875MHz to 20MHz 0.14 MHz kHz 1.0 psRMS 25MHz LVCMOS or differential input (Notes 9, 10) 0.34 Supply-Noise Induced Phase Spur at LVPECL/LVDS Output (Note 11) -56 dBc Supply-Noise Induced Phase Spur at LVCMOS Output (Note 11) -45 dBc Determinisitic Jitter Induced by Power-Supply Noise LVPECL or LVDS (Note 11) 6 psP-P Nonharmonic and Subharmonic Spurs (Note 12) -70 dBc fOFFSET = 1kHz -111 fOFFSET = 10kHz -113 fOFFSET = 100kHz -119 fOFFSET = 1MHz -136 fOFFSET R 10MHz -147 fOFFSET = 1kHz -115 fOFFSET = 10kHz -116 fOFFSET = 100kHz -122 fOFFSET = 1MHz -139 fOFFSET R 10MHz -149 fOFFSET = 1kHz -117 fOFFSET = 10kHz -119 fOFFSET = 100kHz -125 fOFFSET = 1MHz -142 fOFFSET R 10MHz -151 fOFFSET = 1kHz -122 fOFFSET = 10kHz -123 fOFFSET = 100kHz -129 fOFFSET = 1MHz -145 fOFFSET R 10MHz -152 SSB Phase Noise at 491.52MHz SSB Phase Noise at 312.5MHz SSB Phase Noise at 245.76MHz SSB Phase Noise at 156.25MHz 4 42 MHz dBc/ Hz dBc/ Hz dBc/ Hz dBc/ Hz Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs (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. Signal applied to CIN or DIN/DIN only when selected as the reference clock.) (Note 1) PARAMETER SYMBOL SSB Phase Noise at 125MHz SSB Phase Noise at 100MHz CONDITIONS MIN TYP fOFFSET = 1kHz -123 fOFFSET = 10kHz -124 fOFFSET = 100kHz -130 fOFFSET = 1MHz -147 fOFFSET R 10MHz -153 fOFFSET = 1kHz -126 fOFFSET = 10kHz -127 fOFFSET = 100kHz -133 fOFFSET = 1MHz -148 fOFFSET R 10MHz -152 MAX UNITS dBc/ Hz dBc/ Hz Note 1: A series resistor of up to 10.5I is allowed between VCC and VCCA for filtering supply noise when system power-supply tolerance is VCC = 3.3V Q5%. See Figure 3. Note 2: Measured with all outputs enabled and unloaded. Note 3: CIN can be AC- or DC-coupled. See Figure 8. Input high voltage must be ≤ VCC + 0.3V. Note 4: DIN can be AC- or DC-coupled. See Figure 10. Note 5: Measured with 100I differential load. Note 6: Measured with crystal input, or with 50% duty cycle LVCMOS or differential input. Note 7: Measured with output termination of 50I to VCC - 2V or Thevenin equivalent. Note 8: Measured with a series resistor of 33I to a load capacitance of 3.0pF. See Figure 1. Note 9: Measured at 156.25MHz. Note 10: Measured using LVCMOS/LVTTL input with slew rate R 1.0V/ns, or differential input with slew rate R 0.5V/ns. Note 11: Measured at 156.25MHz output with 200kHz, 50mVP-P sinusoidal signal on the supply using the crystal input and the power-supply filter shown in Figure 3. See the Typical Operating Characteristics for other supply noise frequencies. Deterministic jitter is calculated from the measured power-supply-induced spurs. For more information, refer to Application Note 4461: HFAN-04.5.5: Characterizing Power-Supply Noise Rejection in PLL Clock Synthesizers. Note 12: Measured with all outputs enabled and all three banks at different frequencies. LVCMOS QCC 33Ω 499Ω Z = 50Ω OSCILLOSCOPE 0.1µF Z = 50Ω 3pF 50Ω MAX3639 Figure 1. LVCMOS Output Measurement Setup 5 MAX3639 ELECTRICAL CHARACTERISTICS (continued) Typical Operating Characteristics (VCC = 3.3V, TA = +25NC, unless otherwise noted.) PLL BYPASS, ALL OUTPUTS LOADED 250 PLL NORMAL, ALL OUTPUTS UNLOADED 200 150 400 PLL NORMAL 350 300 250 200 150 PLL BYPASS 400 300 150 100 50 10 35 60 0 85 QA[2:0] ENABLED 200 50 -15 QA[4:3] AND QA[2:0] ENABLED 250 50 -40 QA[4:3], QA[2:0], AND QB[2:0] ENABLED 350 100 PLL BYPASS, ALL OUTPUTS UNLOADED QA[4:3], QA[2:0], QB[2:0], QC, AND QCC ENABLED 450 100 0 ALL OUTPUTS DISABLED 0 -40 -15 10 35 60 85 -40 -15 10 35 60 85 TEMPERATURE (°C) TEMPERATURE (°C) TEMPERATURE (°C) SUPPLY CURRENT vs. TEMPERATURE (LVDS OUTPUTS) DIFFERENTIAL OUTPUT AT 737.28MHz (LVPECL) DIFFERENTIAL OUTPUT AT 312.5MHz (LVPECL) QA[4:3], QA[2:0], QB[2:0], QC, AND QCC ENABLED 300 250 QA[4:3], QA[2:0], AND QB[2:0] ENABLED 200 QA[4:3] AND QA[2:0] ENABLED 150 QA[2:0] ENABLED 100 MAX3639 toc06 MAX3639 toc04 MAX3639 toc05 350 SUPPLY CURRENT (mA) 500 SUPPLY CURRENT (mA) 350 300 450 SUPPLY CURRENT (mA) 400 SUPPLY CURRENT vs. TEMPERATURE (LVPECL OUTPUTS, ALL LOADED) MAX3639 toc02 PLL NORMAL, ALL OUTPUTS LOADED 450 500 MAX3639 toc01 500 SUPPLY CURRENT vs. TEMPERATURE (LVDS OUTPUTS, ALL ENABLED) MAX3639 toc03 SUPPLY CURRENT vs. TEMPERATURE (LVPECL OUTPUTS, ALL ENABLED) SUPPLY CURRENT (mA) MAX3639 Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs 200mV/div 200mV/div ALL OUTPUTS DISABLED 50 0 -40 -15 10 35 60 85 200ps/div 500ps/div DIFFERENTIAL OUTPUT AT 156.25MHz (LVPECL) DIFFERENTIAL OUTPUT AT 156.25MHz (LVDS) QCC OUTPUT AT 125MHz (LVCMOS) MAX3639 toc07 MAX3639 toc08 TEMPERATURE (°C) 200mV/div 100mV/div 1ns/div 6 MAX3639 toc09 500mV/div 1ns/div 1ns/div Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs DIFFERENTIAL OUTPUT SWING vs. TEMPERATURE LVDS 1000 500 LVCMOS 2000 LVPECL 1500 LVDS 1000 LVPECL 0 -40 1000 -15 OUTPUT FREQUENCY (MHz) LVPECL/LVDS 50.2 50.0 49.8 49.6 -80 LVCMOS 49.4 -90 -100 -110 -120 -130 -140 -110 -120 -130 -140 -150 85 1k TEMPERATURE (°C) 100k 1M 10M 100M 1k -100 -110 -120 -130 -90 -100 -110 -120 -130 -90 -110 -120 -130 -150 -150 -150 -160 -160 -160 100k 1M 10M OUTPUT FREQUENCY (Hz) 100M 100M -100 -140 10k 10M -80 -140 1k 1M PHASE JITTER = 0.34psRMS INTEGRATED 12kHz TO 20MHz -70 PHASE NOISE (dBc/Hz) -90 100k PHASE NOISE AT 156.25MHz -60 MAX3639 toc17 -80 PHASE NOISE (dBc/Hz) -80 PHASE JITTER = 0.28psRMS INTEGRATED 12kHz TO 20MHz -70 10k OUTPUT FREQUENCY (Hz) PHASE NOISE AT 245.76MHz -60 MAX3639 toc16 PHASE JITTER = 0.32psRMS INTEGRATED 12kHz TO 20MHz -70 10k OUTPUT FREQUENCY (Hz) PHASE NOISE AT 312.5MHz -60 85 -90 -160 60 60 -100 -160 35 35 -80 49.0 10 10 PHASE JITTER = 0.28psRMS INTEGRATED 12kHz TO 20MHz -70 -150 -15 -15 PHASE NOISE AT 491.52MHz -60 49.2 -40 PHASE NOISE (dBc/Hz) -40 PHASE NOISE (dBc/Hz) 50.4 85 TEMPERATURE (°C) PHASE JITTER = 0.27psRMS INTEGRATED 12kHz TO 20MHz -70 PHASE NOISE (dBc/Hz) 50.6 60 PHASE NOISE AT 622.08MHz -60 MAX3639 toc13 DUTY-CYCLE DISTORTION (%) 50.8 35 TEMPERATURE (°C) DUTY-CYCLE DISTORTION vs. TEMPERATURE 51.0 10 MAX3639 toc14 100 10 LVDS 200 100 500 0 0 300 MAX3639 toc15 1500 2500 LVCMOS 400 MAX3639 toc18 LVPECL 2000 3000 RISE/FALL TIME (ps) LVCMOS 2500 500 MAX3639 toc11 3000 3500 DIFFERENTIAL OUTPUT SWING (mVP-P) MAX3639 toc10 DIFFERNETIAL OUTPUT SWING (mVP-P) 3500 RISE/FALL TIME vs. TEMPERATURE (20% TO 80%) MAX3639 toc12 DIFFERENTIAL OUTPUT SWING vs. OUTPUT FREQUENCY -140 1k 10k 100k 1M 10M OUTPUT FREQUENCY (Hz) 100M 1k 10k 100k 1M 10M 100M OUTPUT FREQUENCY (Hz) 7 MAX3639 Typical Operating Characteristics (continued) (VCC = 3.3V, TA = +25NC, unless otherwise noted.) Typical Operating Characteristics (continued) (VCC = 3.3V, TA = +25NC, unless otherwise noted.) MAX3639 toc19 -80 PHASE NOISE (dBc/Hz) -80 -90 -100 -110 -120 -130 PHASE JITTER = 0.36psRMS INTEGRATED 12kHz TO 20MHz -70 -90 -100 -110 -120 -130 -90 -100 -110 -120 -130 -140 -150 -150 -150 -160 -160 -160 100k 1M 10M 100M 10k 1k 100k 1M 10M 100M 0.45 LVCMOS 0.40 0.35 0.30 LVPECL 0.25 MAX3639 toc23 0 -5 JITTER TRANSFER (dB) 0.50 -10 -15 -20 -25 -30 -35 -40 LVDS -45 0.20 -50 -40 -15 10 35 60 85 1k -10 -20 LVCMOS -30 -40 -50 -60 LVDS -70 LVPECL -80 40 fC = 156.25MHz, NOISE = 50mVP-P 30 100 10M LVCMOS 25 20 LVPECL 15 10 LVDS 0 NOISE FREQUENCY (kHz) 1M 35 5 -90 10 100k DETERMINISTIC JITTER INDUCED BY POWER SUPPLY NOISE vs. NOISE FREQUENCY DETERMINISTIC JITTER (psP-P) fC = 156.25MHz, NOISE = 50mVP-P MAX3639 toc24 SPURS INDUCED BY POWER-SUPPLY NOISE vs. NOISE FREQUENCY 0 10k JITTER FREQUENCY (Hz) TEMPERATURE (°C) SPUR AMPLITUDE (dBc) 1M JITTER TRANSFER 5 MAX3639 toc22 INTEGRATED PHASE JITTER (psRMS) OUTPUT FREQUENCY = 156.25MHz 0.55 100k 1000 10M OUTPUT FREQUENCY (Hz) INTEGRATED PHASE JITTER (12kHz TO 20MHz) vs. TEMPERATURE 0.60 10k 1k OUTPUT FREQUENCY (Hz) MAX3639 toc25 10k -140 OUTPUT FREQUENCY (Hz) 8 -80 -140 1k PHASE JITTER = 0.40psRMS INTEGRATED 12kHz TO 20MHz -70 PHASE NOISE (dBc/Hz) PHASE JITTER = 0.36psRMS INTEGRATED 12kHz TO 20MHz -70 PHASE NOISE AT 62.5MHz -60 MAX3639 toc21 PHASE NOISE AT 100MHz -60 MAX3639 toc20 PHASE NOISE AT 125MHz -60 PHASE NOISE (dBc/Hz) MAX3639 Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs 10 100 NOISE FREQUENCY (kHz) 1000 100M Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs PIN NAME MAX3639 Pin Description FUNCTION 1 DM LVCMOS/LVTTL Input. Three-level control for input divider M. See Table 3. 2 XIN Crystal Oscillator Input 3 XOUT 4 VCC Crystal Oscillator Output Core Power Supply. Connect to +3.3V. 5 IN_SEL LVCMOS/LVTTL Input. Three-level control for input mux. See Table 1. 6 PLL_BP LVCMOS/LVTTL Input. Three-level control for PLL bypass mode. See Table 2. 7, 8 DF1, DF0 LVCMOS/LVTTL Inputs. Three-level controls for feedback divider F. See Table 4. 9 QC_CTRL LVCMOS/LVTTL Input. Three-level control input for C-bank output interface. See Table 10. 10 VCCA 11, 12 DP1, DP0 Power Supply for Internal Voltage-Controlled Oscillators (VCOs). See Figure 3. LVCMOS/LVTTL Inputs. Three-level controls for VCO select and prescale divider P. See Table 7. 13, 14 DB1, DB0 LVCMOS/LVTTL Inputs. Three-level controls for output divider B. See Table 5. 15, 16 DA1, DA0 LVCMOS/LVTTL Inputs. Three-level controls for output divider A. See Table 5. 17, 18 DC1, DC0 LVCMOS/LVTTL Inputs. Three-level controls for output divider C. See Table 6. 19 QA_CTRL2 LVCMOS/LVTTL Input. Three-level control for QA[4:3] output interface. See Table 8. 20 VCCQCC 21 QCC 22, 23 C-Bank Differential Output. Configured as LVPECL or LVDS with the QC_CTRL pin. 24 QC, QC VCCQC 25, 36 VCCQA Power Supply for A-Bank Differential Outputs. Connect to +3.3V. 26, 27 QA4, QA4 A-Bank Differential Output. Configured as LVPECL or LVDS with the QA_CTRL2 pin. 28, 29 QA3, QA3 A-Bank Differential Output. Configured as LVPECL or LVDS with the QA_CTRL2 pin. 30, 31 QA2, QA2 A-Bank Differential Output. Configured as LVPECL or LVDS with the QA_CTRL1 pin. 32, 33 QA1, QA1 A-Bank Differential Output. Configured as LVPECL or LVDS with the QA_CTRL1 pin. 34, 35 A-Bank Differential Output. Configured as LVPECL or LVDS with the QA_CTRL1 pin. 37 QA0, QA0 VCCQB 38, 39 QB0, QB0 B-Bank Differential Output. Configured as LVPECL or LVDS with the QB_CTRL pin. 40, 41 QB1, QB1 B-Bank Differential Output. Configured as LVPECL or LVDS with the QB_CTRL pin. 42, 43 B-Bank Differential Output. Configured as LVPECL or LVDS with the QB_CTRL pin. 44 QB2, QB2 QA_CTRL1 45 QB_CTRL LVCMOS/LVTTL Input. Three-level control for B-bank output interface. See Table 9. 46, 47 DIN, DIN Differential Clock Input. Operates up to 350MHz. This input can accept DC-coupled LVPECL signals, and is internally biased to accept AC-coupled LVDS, CML, and LVPECL signals. 48 CIN LVCMOS Clock Input. Operates up to 160MHz. — EP Exposed Pad. Connect to supply ground for proper electrical and thermal performance. Power Supply for QCC Output. Connect to +3.3V. C-Bank LVCMOS Clock Output Power Supply for C-Bank Differential Output. Connect to +3.3V. Power Supply for B-Bank Differential Outputs. Connect to +3.3V. LVCMOS/LVTTL Input. Three-level control for QA[2:0] output interface. See Table 8. 9 MAX3639 Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs Detailed Description banks of clock outputs. See Figure 2. The output banks include nine pin-programmable LVDS/LVPECL output buffers and one LVCMOS output buffer. The frequency, enabling, and output interface of each output bank can be individually programmed. In addition the A-bank is split into two banks with programmable enabling and The MAX3639 is a low-jitter clock generator designed to operate over a wide range of frequencies. It consists of a selectable reference clock (on-chip crystal oscillator, LVCMOS input, or differential input), PLL with on-chip VCO, pin-programmable dividers and muxes, and three IN_SEL VCC DM DP[1:0] VCCA 2 DA[1:0] PLL_BP VCCQA QA_CTRL1 2 QA0 VCO SELECT XOUT CRYSTAL OSCILLATOR 1 0 XIN fREF LVCMOS CIN QA0 QA1 NC ÷M PFD VCO CP fVCO ÷P ÷A fQA QA1 QA2 0/NC QA2 fPFD 15MHz TO 42MHz 3600MHz TO 3830MHz OR 3830MHz TO 4025MHz QA3 QA3 LVPECL DIN DIN QA4 ÷F QA4 1 QA_CTRL2 VCCQB QB_CTRL QB0 MAX3639 QB0 QB1 1 ÷B fQB QB1 QB2 0/NC QB2 DIVIDER A: 1, 2, 3, 4, 5, 6, 8, 12, 16 DIVIDER B: 1, 2, 3, 4, 5, 6, 8, 12, 16 DIVIDER C: 2, 3, 4, 5, 6, 8, 12, 16, 24 DIVIDER F: 16, 20, 24, 25, 28, 30, 32, 40, 48 DIVIDER M: 1, 2, 4 DIVIDER P: 4, 5, 6, 7, 8, 9, 10 QC_CTRL QC 1/NC ÷C 2 EP Figure 2. Detailed Functional Diagram 10 DF[1:0] 2 DB[1:0] fQC QC 0 QCC 2 DC[1:0] VCCQC VCCQCC Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs Crystal Oscillator The on-chip crystal oscillator provides the low-frequency reference clock for the PLL. This oscillator requires an external crystal connected between XIN and XOUT. See the Crystal Selection and Layout section for more information. The XIN and XOUT pins can be left open if not used. LVCMOS Clock Input An LVCMOS-compatible clock source can be connected to CIN to serve as the PLL reference clock. The input is internally biased to allow AC- or DC-coupling (see the Applications Information section). It is designed to operate from 15MHz to 160MHz. No signal should be applied to CIN if not used. Differential Clock Input A differential clock source can be connected to DIN to serve as the PLL reference clock. This input operates from 15MHz to 350MHz and contains an internal 100ω differential termination. This input can accept DC-coupled LVPECL signals, and is internally biased to accept AC-coupled LVDS, CML, and LVPECL signals (see the Applications Information section). No signal should be applied to DIN if not used. Phase-Locked Loop (PLL) The PLL takes the signal from the crystal oscillator, LVCMOS clock input, or differential clock input and synthesizes a low-jitter, high-frequency clock. The PLL contains a phase-frequency detector (PFD), a charge pump (CP), and two low phase noise VCOs that combined give a wide 3.60GHz to 4.025GHz frequency range. The high-frequency VCO output is divided by prescale divider P and then is connected to the PFD input through a feedback divider F. The PFD compares the reference frequency to the divided-down VCO output and generates a control signal that keeps the VCO locked to the reference clock. The high-frequency VCO/P output clock is sent to the output dividers. To minimize noise-induced jitter, the VCO supply (VCCA) is isolated from the core logic and output buffer supplies. Dividers and Muxes The dividers and muxes are set with three-level control inputs. Divider settings and routing information are given in Tables 1 to 7. See Table 11 for example divider configurations used in various applications. Table 1. PLL Input IN_SEL INPUT 0 Crystal Input. XO circuit is disabled when not selected. 1 Differential Input. No signal should be applied to DIN if not selected NC LVCMOS Input. No signal should be applied to CIN if not selected. Table 2. PLL Bypass PLL_BP PLL OPERATION 0 PLL Enabled for Normal Operation. All outputs from the A, B, and C banks are derived from the VCO. 1 PLL Bypassed. Selected input passes directly to the outputs. Both VCOs are disabled to minimize power consumption and intermodulation spurs. Used for system testing or clock distribution. NC The outputs from A-bank and B-bank are derived from the VCO, but the C-bank outputs are directly driven from the input signal for purposes of daisy chaining. 11 MAX3639 output interface. A PLL bypass mode is also available for system testing or clock distribution. MAX3639 Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs Table 3. Input Divider M Table 7. VCO Select and Prescale Divider P DM M DIVIDER RATIO 0 ÷1 1 ÷2 NC ÷4 DP1 Note: When the on-chip XO is selected (IN_SEL = 0), the setting DM = 0 is required. DP0 0 0 1 NC Table 4. PLL Feedback Divider F DF1 DF0 F DIVIDER RATIO Low (3600 to 3830) 0 NC 1 P DIVIDER RATIO (VCO/P) FREQUENCY RANGE (MHz) ÷5 720 to 766 ÷6 600 to 638.33 ÷9 400 to 425.50 ÷7 547.14 to 575 ÷10 383 to 402.50 ÷8 0 0 ÷25 NC 0 1 ÷20 0 1 0 ÷16 1 1 ÷32 1 NC ÷24 NC 1 ÷30 0 NC ÷40 NC 0 ÷48 QA_CTRL1 NC NC ÷28 0 QA[2:0] = LVDS 1 QA[2:0] = LVPECL NC QA[2:0] disabled to high impedance QA_CTRL2 QA[4:3] OUTPUT Table 5. Output Divider A, B DA1/DB1 DA0/DB0 A, B DIVIDER RATIO 0 0 ÷2 0 1 ÷3 1 0 ÷4 1 1 ÷5 1 NC ÷6 1 1 ÷5 478.75 to 503.12 957.50 to 1006.25 766 to 805 NC ÷6 638.33 to 670.83 High (3830 to 4025) ÷4 Table 8. A-Bank Output Interface QA[2:0] OUTPUT 0 QA[4:3] = LVDS 1 QA[4:3] = LVPECL NC QA[4:3] disabled to high impedance Table 9. B-Bank Output Interface NC 1 ÷8 QB_CTRL 0 NC ÷12 0 QB[2:0] = LVDS QB[2:0] = LVPECL QB[2:0] disabled to high impedance NC 0 ÷16 1 NC NC ÷1 NC QB[2:0] OUTPUT Table 10. C-Bank Output Interface Table 6. Output Divider C 12 VCO FREQUENCY RANGE (MHz) DC1 DC0 C DIVIDER RATIO QC_CTRL 0 0 ÷2 0 QC = LVDS, QCC = LVCMOS 0 1 ÷3 1 QC = LVPECL, QCC = LVCMOS 1 0 ÷4 NC QC and QCC disabled to high impedance 1 1 ÷5 1 NC ÷6 NC 1 ÷8 0 NC ÷12 NC 0 ÷16 NC NC ÷24 QC AND QCC OUTPUT LVDS/LVPECL Clock Outputs The differential clock outputs (QA[4:0], QB[2:0], QC) operate up to 800MHz and have a pin-programmable LVDS/LVPECL output interface. See Tables 8 to 10. When configured as LVDS, the buffers are designed to drive transmission lines with a 100ω differential Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs LVCMOS Clock Output The LVCMOS clock output operates up to 160MHz and is designed to drive a single-ended high-impedance load. If unused, this output can be left open or the C-bank can be disabled to high impedance. Internal Reset During power-on, a power-on reset (POR) signal is generated to synchronize all dividers. A reset signal is also generated if any control pin is changed. Outputs within a bank are phase aligned, but outputs bank-to-bank may not be phase aligned. Applications Information Output Frequency Configuration The MAX3639 output frequencies (fQA, fQB, fQC) are functions of the reference frequency (fREF) and the pinprogrammable dividers (A, B, C, F, M). The relationships can be expressed as: f F fQA = REF × M A (1) f F fQB = REF × M B (2) f F fQC = REF × M C (3) 3600MHz ≤ fVCO ≤ 3830MHz (when DP1 = 0) (5) 3830MHz ≤ fVCO ≤ 4025MHz (when DP1 = 1 or NC) (6) The prescale divider P is set by pins DP1 and DP0 as given in Table 7. In addition, the reference clock frequency and input divider M must also be selected so the PFD compare frequency (fPFD) falls within the specified range of 15MHz to 42MHz. If applicable, the higher fPFD should be selected for optimal jitter performance. f f fPFD = REF = VCO M P ×F (7) 15MHz ≤ fPFD ≤ 42MHz (8) Note that the reference clock frequency is not limited by the fPFD range when the PLL is in bypass mode. Example Frequency Configuration The following is an example of how to find divider ratios for a valid PLL configuration, given a requirement of input and output frequencies. 1) S elect input and output frequencies for an Ethernet application. fREF = 25MHz fQA = 312.5MHz fQB = 156.25MHz fQC = 125MHz 2) F ind the input divider M for a valid PFD compare frequency. Using Table 3 and equations (7) and (8), it is determined that M = ÷1 is the only valid option. The frequency ranges for the selected reference clocks are 18MHz to 33.5MHz for the crystal oscillator input, 15MHz to 160MHz for the LVCMOS input, and 15MHz to 350MHz for the differential input. The available dividers are given in Tables 3 to 6. 3) F ind the feedback divider F and prescale divider P for a valid fVCO. Using Tables 4 and 7 along with equations (4), (5), and (6), it is determined that F = ÷25 and P = ÷6 results in fVCO = 3750MHz, which is within the valid range of the low VCO. For a given reference frequency fREF, the input divider M, the PLL feedback divider F, and VCO prescale divider P must be configured so the VCO frequency (fVCO) falls within the specified ranges. Invalid PLL configuration leads to VCO frequencies beyond the specified ranges and can result in loss of lock. An expression for the VCO frequency along with the specified ranges is given by: 4) F ind the output dividers A, B, C for the required output frequencies. Using Tables 5 and 6 and equations (1), (2), and (3), it is determined that A = ÷2 gives fQA = 312.5MHz, B = ÷4 gives fQB = 156.25MHz, and C = ÷5 gives fQC = 125MHz. f fVCO = REF × F × P M Table 11 provides input and output frequencies along with valid divider ratios for a variety of applications. (4) 13 MAX3639 termination. When configured as LVPECL, the buffers are designed to drive transmission lines terminated with 50ω to VCC - 2V. Unused output banks can be disabled to high impedance and unused outputs can be left open. MAX3639 Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs Table 11. Reference Frequencies and Divider Ratios for Various Applications fREF (MHz) INPUT DIVIDER (M) PLL FEEDBACK DIVIDER (F) 15.36 1 48 30.72 1 24 61.44 2 24 122.88 4 VCO FREQUENCY (MHz) 3686.4 24 VCO PRESCALE DIVIDER (P) OUTPUT DIVIDER (A, B, C) OUTPUT FREQUENCY (MHz) 5 1 737.28 5 2 368.64 5 3 245.76 5 4 184.32 5 6 122.88 5 8 92.16 5 12 61.44 5 24 30.72 15.36 1 40 6 1 614.4 19.2 1 32 6 2 307.2 30.72 1 20 6 3 204.8 6 4 153.6 6 5 122.88 38.4 1 16 61.44 2 20 3686.4 76.8 2 16 6 6 102.4 122.88 4 20 6 8 76.8 153.6 4 16 6 12 51.2 30.72 1 32 4 (8) 2 (1) 491.52 61.44 2 32 4 (8) 4 (2) 245.76 4 (8) 8 (4) 122.88 3932.16 122.88 4 32 4 (8) 16 (8) 61.44 13 1 32 9 1 416 26 1 16 9 4 104 9 8 52 9 16 26 6 1 625 6 2 312.5 6 4 156.25 6 5 125 5 3 250 5 4 187.5 5 5 150 52 25/31.25/ 62.5/125/ 156.25 26.04166 25/31.25/ 62.5/125 2 1/1/2/4/4 3744 16 25/20/20/ 20/16 3750 1 1/1/2/4 24 30/24/24/24 3750 5 6 125 5 12 62.5 cdma2000 is a registered trademark of the Telecommunications Industry Association. WiMAX is a trademark of WiMAX Forum. 14 APPLICATIONS Wireless Base Station: WCDMA, cdma2000®, LTE, TD_SCDMA, WiMAX™, GSM GSM Ethernet Ethernet Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs fREF (MHz) 26.5625 INPUT DIVIDER (M) 1 PLL FEEDBACK DIVIDER (F) 24 VCO FREQUENCY (MHz) 3825 VCO PRESCALE DIVIDER (P) OUTPUT DIVIDER (A, B, C) OUTPUT FREQUENCY (MHz) 6 2 318.75 6 3 212.5 6 4 159.375 6 6 106.25 6 12 53.125 19.44 1 32 6 1 622.08 38.88 1 16 6 2 311.04 6 4 155.52 6 8 77.76 6 16 38.88 5 2 400 5 3 266.67 5 4 200 5 6 133.333 5 8 100 5 12 66.67 5 16 50 3732.48 155.52 33.3/66.7/ 133.3 4 1/2/4 16 24 4000 25/50/100 1/2/4 32 33.3/66.7/ 133.3 1/2/4 30 4 2 500 25/50/100 1/2/4/8 40 4 3 333.33 4 4 250 4 5 200 4 6 166.67 4 8 125 5 6 131.04 5 12 65.52 6 1 666.514 6 2 333.257 6 4 166.6285 6 1 644.53125 6 4 161.1328125 6 1 657.421875 6 4 164.355 6 1 669.3265 6 2 334.66 6 4 167.33 4000 31.25/ 62.5/125 32.76 1/2/4 1 20.82857 41.6571 32 24 3931.2 32 1 16 3999.084 25.78125 1 25 3867.1875 27.392578 1 24 3944.53125 20.916 1 32 41.8329 1 16 4015.95949 APPLICATIONS FC-SAN SONET/SDH, STM-N Server, FB-DIMM, Network Processor, DDR/QDR Memory, PCIe, SATA Server, FB-DIMM, Processor Clock and DDR/QDR Memory, PCIe, SATA Microwave Radio Link OTU1, 10Gbps SONET with FEC 10Gbps Ethernet with FEC 10Gbps FC OTU2, 10Gbps SONET with Digital Wrapper 15 MAX3639 Table 11. Reference Frequencies and Divider Ratios for Various Applications (continued) MAX3639 Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs Power-Supply Filtering The MAX3639 is a mixed analog/digital IC. The PLL contains analog circuitry susceptible to random noise. To take full advantage of on-board filtering and noise attenuation, in addition to excellent on-chip power-supply rejection, this part provides a separate power-supply pin, VCCA, for the VCO circuitry. Figure 3 illustrates the recommended power-supply filter network for VCCA. The purpose of this design technique is to ensure clean input power supply to the VCO circuitry and to improve the overall immunity to power-supply noise. This network requires that the power supply is +3.3V ±5%. Decoupling capacitors should be used on all other supply pins for best performance. All supply connections should be driven from the same source. +3.3V ±5% VCC 0.1µF 10.5Ω MAX3639 VCCA 0.1µF 10µF Figure 3. Power-Supply Filter Ground Connection The 48-pin TQFN package features an exposed pad (EP), which provides a low resistance thermal path for heat removal from the IC and also the electrical ground. For proper operation, the EP must be connected to the circuit board ground plane with multiple vias. Crystal Selection and Layout The MAX3639 features an integrated on-chip crystal oscillator to minimize system implementation cost. The crystal oscillator is designed to drive a fundamental mode, AT-cut crystal resonator. See Table 12 for recommended crystal specifications. See Figure 4 for the crystal equivalent circuit and Figure 5 for the recommended external capacitor connections. The crystal, trace, and two external capacitors should be placed on the board as close as possible to the XIN and XOUT pins to reduce crosstalk of active signals into the oscillator. The total load capacitance for the crystal is a combination of external and on-chip capacitance. The layout shown in Figure 6 gives approximately 1.7pF of trace plus footprint capacitance per side of the crystal. Note the ground plane is removed under the crystal to minimize capacitance. There is approximately 2.5pF of on-chip capacitance between XIN and XOUT. With an external 27pF capacitor connected to XIN and a 33pF capacitor connected to XOUT, the total load capacitance for the crystal is approximately 18pF. The XIN and XOUT pins can be left open if not used. Table 12. Crystal Selection Parameters PARAMETER Crystal Oscillation Frequency SYMBOL MIN fOSC 18 TYP MAX UNITS 25 33.5 MHz Shunt Capacitance C0 2.0 7.0 pF Load Capacitance CL 18 Equivalent Series Resistance (ESR) RS 10 pF Maximum Crystal Drive Level XTAL 50 I 200 FW 27pF XIN CRYSTAL (CL = 18pF) C0 RS LS Figure 4. Crystal Equivalent Circuit 16 CS MAX3639 XOUT 33pF Figure 5. Crystal, Capacitor Connections Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs Interfacing with Differential Input The equivalent input circuit for DIN is given in Figure 9. This input operates up to 350MHz and contains an internal 100I differential termination as well as a 35I common-mode termination. The common-mode termination ensures good signal integrity when connected to a source with large common-mode signals. The input can accept DC-coupled LVPECL signals, and is internally biased to accept AC-coupled LVDS, CML, and LVPECL signals (Figure 10). No signal should be applied to DIN if not used. Figure 6. Crystal Layout 1.4V VCC VBIAS VCC 180kΩ CIN VCC ESD STRUCTURES ESD STRUCTURES DIN Figure 7. Equivalent CIN Circuit 50Ω 20kΩ 10Ω VCC VCC - 1.3V 16pF 50Ω DC-COUPLED MAX3639 20kΩ DIN CIN XO ESD STRUCTURES Figure 9. Equivalent DIN Circuit AC-COUPLED MAX3639 0.1µF XO CIN Figure 8. Interface to CIN 17 MAX3639 Interfacing with LVCMOS Input The equivalent LVCMOS input circuit for CIN is given in Figure 7. This input is internally biased to allow AC- or DC-coupling, and has 180kI input impedance. See Figure 8 for the interface circuit. No signal should be applied to CIN if not used. Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs MAX3639 Interfacing with LVPECL Outputs LVPECL SOURCE DRIVING MAX3639 DIFFERENTIAL INPUT DC-COUPLED MAX3639 150Ω +3.3V +3.3V DIN Z = 50Ω LVPECL 100Ω LVPECL DIN Z = 50Ω The equivalent LVPECL output circuit is given in Figure 11. These outputs are designed to drive a pair of 50ω transmission lines terminated with 50ω to VTT = VCC - 2V. If a separate termination voltage (VTT) is not available, other terminations methods can be used, as shown in Figure 12. For more information on LVPECL terminations and how to interface with other logic families, refer to Application Note 291: HFAN-01.0: Introduction to LVDS, PECL, and CML. 150Ω VCC_ _ LVPECL SOURCE DRIVING MAX3639 DIFFERENTIAL INPUT AC-COUPLED +3.3V MAX3639 150Ω 0.1µF Z = 50Ω LVPECL 0.1µF Z = 50Ω +3.3V DIN 100Ω Q_ _ LVPECL Q_ _ DIN 150Ω ESD STRUCTURES LVDS OR CML SOURCE DRIVING MAX3639 DIFFERENTIAL INPUT AC-COUPLED VDD 0.1µF Z = 50Ω LVDS OR CML 0.1µF Z = 50Ω Figure 10. Interfacing to DIN 18 Figure 11. Equivalent LVPECL Output Circuit MAX3639 +3.3V DIN 100Ω DIN LVPECL Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs MAX3639 DC-COUPLED LVPECL DRIVING THEVENIN EQUIVALENT TERMINATION +3.3V +3.3V +3.3V 130Ω MAX3639 Q_ _ +3.3V 130Ω HIGH IMPEDANCE WITH/WITHOUT DC BIAS Z = 50Ω LVPECL LVPECL Q_ _ Z = 50Ω 82Ω 82Ω AC-COUPLED LVPECL DRIVING INTERNAL 100Ω DIFFERENTIAL TERMINATION +3.3V VDD 150Ω MAX3639 Q_ _ ON-CHIP TERMINATION WITH DC BIAS 0.1µF Z = 50Ω LVPECL 100Ω 0.1µF Q_ _ LVPECL Z = 50Ω 150Ω AC-COUPLED LVPECL DRIVING EXTERNAL 50Ω WITH COMMON-MODE TERMINATION +3.3V VDD 150Ω MAX3639 Q_ _ 0.1µF HIGH IMPEDANCE WITH DC BIAS Z = 50Ω LVPECL LVPECL 0.1µF Q_ _ Z = 50Ω 150Ω 50Ω 50Ω 0.1µF Figure 12. Interface to LVPECL Outputs 19 MAX3639 Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs VREG Interfacing with LVDS Outputs VCC_ _ 50Ω Q_ _ The equivalent LVDS output circuit is given in Figure 13. These outputs provide 100ω differential output impedance designed to drive a 100ω differential transmission line terminated with a 100ω differential load. Example interface circuits are shown in Figure 14. For more information on LVDS terminations and how to interface with other logic families, refer to Application Note 291: HFAN01.0: Introduction to LVDS, PECL, and CML. 50Ω Q_ _ ESD STRUCTURES Interfacing with LVCMOS Output The equivalent LVCMOS output circuit is given in Figure 15. This output provides 15ω output impedance and is designed to drive a high-impedance load. A series resistor of 33ω is recommended at the LVCMOS output before the transmission line. An example interface circuit is shown in Figure 16. Figure 13. Equivalent LVDS Output Circuit VCCQCC DC-COUPLED LVDS OUTPUT DRIVING LVDS INPUT +3.3V +3.3V 10Ω MAX3639 Q_ _ Z = 50Ω LVDS QCC LVDS* Q_ _ 10Ω Z = 50Ω ESD STRUCTURES Figure 15. Equivalent LVCMOS Output Circuit AC-COUPLED LVDS OUTPUT DRIVING LVDS INPUT +3.3V MAX3639 VDD Q_ _ LVDS Q_ _ 0.1µF Z = 50Ω LVDS* 0.1µF LVCMOS QCC 33Ω Z = 50Ω Z = 50Ω MAX3639 *100Ω DIFFERENTIAL INPUT IMPEDANCE ASSUMED. Figure 14. Interface to LVDS Outputs 20 Figure 16. Interface to LVCMOS Output HIGH IMPEDANCE Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs • T he crystal, trace, and two external capacitors should be placed on the board as close as possible to the XIN and XOUT pins to reduce crosstalk of active signals into the oscillator. • M aintain 100ω differential (or 50ω single-ended) transmission line impedance into and out of the part. • A n uninterrupted ground plane should be positioned beneath the clock outputs. The ground plane under the crystal should be removed to minimize capacitance. • P rovide space between differential output pairs to reduce crosstalk, especially if the outputs are operating at different frequencies. • U se multilayer boards with an uninterrupted ground plane to minimize EMI and crosstalk. • S upply decoupling capacitors should be placed close to the supply pins, preferably on the same side of the board as the MAX3639. Refer to the MAX3639 evaluation kit for more information. Chip Information • T ake care to isolate input traces from the MAX3639 outputs. PROCESS: BiCMOS QA0 QA1 QA1 QA2 QA2 QA3 QA3 QA4 QA4 VCCQA 36 QA0 TOP VIEW VCCQA Pin Configuration 35 34 33 32 31 30 29 28 27 26 25 VCCQB 37 24 VCCQC QB0 38 23 QC QB0 39 22 QC QB1 40 21 QCC QB1 41 20 VCCQCC QB2 42 19 QA_CTRL2 DC0 MAX3639 QB2 43 18 QA_CTRL1 44 17 DC1 QB_CTRL 45 16 DA0 DIN 46 15 DA1 14 DB0 13 DB1 4 5 6 7 8 9 10 11 12 PLL_BP DF1 DF0 QC_CTRL VCCA DP1 DP0 3 VCC 2 IN_SEL 1 XOUT 48 XIN 47 CIN DM DIN *EP + THIN QFN (7mm × 7mm × 0.8mm) *THE EXPOSED PAD OF THE QFN PACKAGE MUST BE SOLDERED TO GROUND FOR PROPER THERMAL AND ELECTRICAL OPERATION. 21 MAX3639 Layout Considerations The inputs and outputs are the most critical paths for the MAX3639; great care should be taken to minimize discontinuities on the transmission lines. Here are some suggestions for maximizing the performance of the MAX3639: Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs MAX3639 Typical Application Circuits +3.3V 10.5Ω 10µF 0.1µF 0.1µF VCCA 27pF VCC 0.1µF VCCQA VCCQB XIN 0.1µF VCCQC 0.1µF 0.1µF VCCQCC 150Ω 312.5MHz LVPECL Z = 50Ω QA[4:0] 0.1µF 25MHz XOUT NC CIN NC DIN NC DIN 100Ω 0.1µF Z = 50Ω QA[4:0] 33pF ASIC WITH LVPECL TERMINATION 150Ω 156.25MHz LVDS Z = 50Ω IN_SEL MAX3639 PLL_BP QB[2:0] ASIC WITH LVDS TERMINATION 100Ω DM DF1 QB[2:0] Z = 50Ω QC 125MHz LVDS Z = 50Ω DF0 DA1 +3.3V DA0 DB1 ASIC WITH LVDS TERMINATION 100Ω DB0 DC1 Z = 50Ω QC DC0 DP1 DP0 33Ω QA_CTRL1 QCC QA_CTRL2 ASIC WITH LVCMOS TERMINATION HIGH IMPEDANCE QB_CTRL QC_CTRL EP 22 125MHz LVCMOS Z = 50Ω Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs CLOCK GENERATOR FOR ETHERNET XIN QA[4:0] 312.5MHz LVPECL OR LVDS BACKPLANE TRANSCEIVER QB[2:0] 156.25MHz LVPECL OR LVDS 10GbE PHY QC 125MHz LVPECL OR LVDS 1GbE PHY QCC 125MHz LVCMOS ASIC 25MHz XOUT MAX3639 FREQUENCY TRANSLATOR FOR BASE STATION 30.72MHz QA[4:0] 122.88MHz LVPECL OR LVDS CPRI SerDes QB[2:0] 153.6MHz LVPECL OR LVDS SRIO QC 30.72MHz LVPECL OR LVDS FPGA QCC 30.72MHz LVCMOS FPGA QA[4:0] 622.08MHz LVPECL OR LVDS OC-192 PHY QB[2:0] 155.52MHz LVPECL OR LVDS OC-48 PHY QC 155.52MHz LVPECL OR LVDS ASIC QCC 38.88MHz LVCMOS ASIC DIN MAX3639 FREQUENCY SYNTHESIZER FOR SONET LINE CARD 19.44MHz DIN MAX3639 23 MAX3639 Typical Application Circuits (continued) Low-Jitter, Wide Frequency Range, Programmable Clock Generator with 10 Outputs MAX3639 Typical Application Circuits (continued) CLOCK GENERATOR FOR SYSTEM CLOCKING XIN QA[4:0] 100MHz LVPECL OR LVDS PCIe QB[2:0] 133.33MHz LVPECL OR LVDS DDR/QDR MEMORY QC 66.67MHz LVPECL OR LVDS NETWORK PROCESSOR QCC 66.67MHz LVCMOS ASIC 25MHz XOUT MAX3639 CLOCK GENERATOR FOR FIBRE CHANNEL XIN QA[4:0] 212.5MHz LVPECL OR LVDS 8G PHY QB[2:0] 106.25MHz LVPECL OR LVDS 4G PHY QC 106.25MHz LVPECL OR LVDS ASIC 26.5625MHz XOUT MAX3639 QCC NC Package Information For the latest package outline information and land patterns, go to www.maxim-ic.com/packages. Note that a “+”, “#”, or “-” in the package code indicates RoHS status only. Package drawings may show a different suffix character, but the drawing pertains to the package regardless of RoHS status. PACKAGE TYPE PACKAGE CODE DOCUMENT NO. 48 TQFN-EP T4877+4 21-0144 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. 24 © 2009 Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 Maxim Integrated Products Maxim is a registered trademark of Maxim Integrated Products, Inc.