SL23EP09NZ Low Jitter and Skew DC to 220 MHz Clock Buffer Key Features Description DC to 220 MHz operating frequency range Low output clock skew: 70ps-typ Low part-to-part output skew: 100 ps-typ Low output propogation delay: 3.5ns-typ 3.3V to 2.5V operation supply voltage range The SL23EP09NZ products operate from DC to 220MHz and within 3.3V to 2.5V power supply range. Low power dissipation - 11 mA-typ at 66MHz at VDD=3.3V - 10 mA-typ at 66MHz at VDD=2.5V One input to nine (9) output fanout buffer drivers Refer to SL2309NZ product for DC to 140MHz-max frequency range. Also refer to SL2304NZ or SL23EP04NZ products for 1:4 clock fanout buffers within 3.3V to 2.5V power supply and DC to 220MHZ frequency range. Available in 16-pin SOIC package Benefits Available in Commercial and Industrial grades Available in Lead (Pb) free package Applications General Purpose PCI/PCI-X Clock Buffer Printers, MFPs and Digital Copiers PCs and Work Stations Routers, Switches and Servers Datacom and Telecom High-Speed Digital Embeded Systems The SL23EP09NZ is a low skew, jitter and power fanout buffer designed to produce up to nine (9) clock outputs from one (1) reference input clock, for high speed clock distribution. Up to nine (9) distribution of input clock Low propogation delay Low output-to-output skew Low output clock jitter Low power dissipation Block Diagram CLKIN OUTPUT1 OUTPUT2 OUTPUT3 OUTPUT4 OUTPUT5 OUTPUT6 OUTPUT7 OUTPUT8 OUTPUT9 VDD(3) GND(3) Rev 2.2, May 6, 2008 400 West Cesar Chavez, Austin, TX 78701 Page 1 of 11 1+(512) 416-8500 1+(512) 416-9669 www.silabs.com SL23EP09NZ Pin Configuration CLKIN 1 16 OUTPUT9 OUTPUT1 2 15 OUTPUT8 OUTPUT2 3 14 OUTPUT7 VDD 4 13 VDD GND 5 12 GND OUTPUT3 6 11 OUTPUT6 OUTPUT4 7 10 OUTPUT5 VDD 8 9 GND 16-Pin SOIC Pin Description Pin Number Pin Name Pin Type 1 CLKIN Input 2 OUTPUT1 Output Buffered Clock Output-1 3 OUTPUT2 Output Buffered Clock Output-2 4 VDD Power 3.3V +/-10% Power Supply 5 GND Power Power Ground 6 OUTPUT3 Output Buffered Clock Output-3 7 OUTPUT4 Output Buffered Clock Output-4 8 VDD Power 3.3V and 2.5V +/-10% Power Supply 9 GND Power Power Ground 10 OUTPUT5 Output Buffered Clock Output-5 11 OUTPUT6 Output Buffered Clock Output-6 12 GND Power Power Ground 13 VDD Power 3.3V and 2.5V +/-10% Power Supply 14 OUTPUT7 Output Buffered Clock Output-7 15 OUTPUT8 Output Buffered Clock Output-8 16 OUTPUT9 Output Buffered Clock Output-9 Rev 2.2, May 6, 2008 Pin Description Input Reference Clock Page 2 of 11 SL23EP09NZ General Description Output Clock Skew The SL23EP09NZ is a low skew, jitter and power fanout buffer designed to produce up to nine (9) clock outputs from one (1) reference input clock, for high speed clock distribution, including PCI/PCI-X applications. All outputs should drive the similar load to achieve outputto-output skew specifications as given in the switching electrical tables. Power Supply Range (VDD) Input and output Frequency Range The SL23EP09NZ is designed to operate from 3.3V to 2.5V VDD power supply range. An internal on-chip voltage regulator is used to provide to constant power supply of 1.8V, leading to a consistent and stable electrical performance in terms of skew and jitter. The SL23EP09NZ I/O is powered by using VDD. The input and output frequency is the same (1x) for SL2309NZ and the product operates from DC to 220MHz clock range with 15pF and 134MHz with 30pF output loads at VDD=3.3V. High Drive Capability The SL23EP09NZ is designed to meet high drive requirements for up to 30pF load condition per electrical specifications tables. If lower drive levels are required refer to SL2309NZ fanout buffer product. Refer to SL2309NZ product for DC to 140MHz-max frequency range. Contact SLI for 1.8V power supply Buffers and ZDB products. Absolute Maximum Ratings (C-Grade and I-Grade) Description Condition Min Max Unit Supply voltage, VDD -0.5 4.2 V All Inputs and Outputs -0.5 VDD+0.5 V Ambient Operating Temperature In operation, C-Grade 0 70 °C Ambient Operating Temperature In operation, I-Grade -40 85 °C Storage Temperature No power is applied -65 150 °C Junction Temperature In operation, power is applied – 125 °C – 260 °C Soldering Temperature ESD Rating (Human Body Model) JEDEC22-A114D -4,000 4,000 V ESD Rating (Charge Device Model) JEDEC22-C101C -1,500 1,500 V ESD Rating (Machine Model) JEDEC22-A115D -200 200 V Rev 2.2, May 6, 2008 Page 3 of 11 SL23EP09NZ Operating Conditions (C-Grade and I-Grade) Unless otherwise stated VDD= 3.3V+/- 10%, CL=15pF Description Symbol Operating Voltage Condition Min Typ Max Unit 2.97 3.3 3.63 V VDD VDD+/-10% TA1 Ambient Temperature C-Grade 0 – 70 °C TA2 Ambient Temperature I-Grade -40 – 85 °C VINC Pin 1 – 5 7 pF CL1 All outputs ≤ 220MHz, 3.3V – – 15 pF CL2 All outputs ≤ 134MHz, 3.3V – – 30 pF Operating Temperature Input Capacitance Load Capacitance Operating Frequency CLKIN Input Clock Range, CL=15pF DC – 220 MHz Operating Frequency CLKIN Input Clock Range, CL=30pF DC – 134 MHz DC Electrical Characteristics (C-Grade) Unless otherwise stated VDD= 3.3V+/- 10%, CL=15pF and Ambient Temperature range 0 to +70°C Description Symbol Condition Min Typ Max Unit Input LOW Voltage VINL CLKIN – – 0.8 V Input HIGH Voltage VINH CLKIN 2.0 – VDD+0.3 V Input LOW Current IINL 0 < VIN < 0.8V – – 10 µA Input HIGH Current IINH 2.4V < VIN < VDD – – 15 µA Output Low Voltage VOL IOL=12mA – – 0.4 V Output High Voltage VOH IOH=-12mA 2.4 – – V Power Supply Current IDD1 CLKIN=33.3MHz, CL=0 – 9 13 mA Power Supply Current IDD2 CLKIN=66.6MHz, CL=0 – 11 16 mA Power Supply Current IDD3 CLKIN=166MHz, CL=0 – 15 20 mA Switching Electrical Characteristics (C-Grade) Unless otherwise stated VDD= 3.3V+/- 10%, CL=15pF and Ambient Temperature range 0 to +70°C Description Symbol Condition Min Typ Max Unit FOUT1 CL=15pf 0 – 220 MHz FOUT2 CL=30pf 0 – 134 MHz Output Frequency Range Input Duty Cycle DC1 Measured at VDD/2 20 50 80 % Output Duty Cycle DC2 CL=15pF, Fout=166MHz Measured at VDD/2 45 50 55 % Output Duty Cycle DC3 CL=30pF, Fout=100MHz Measured at VDD/2 40 50 60 % Output Rise/Fall Time tr/f-1 Measured at 0.8V to 2.0V – – 1.2 ns Rev 2.2, May 6, 2008 Page 4 of 11 SL23EP09NZ CL=15pF Output Rise/Fall Time tr/f-2 Measured at 0.8V to 2.0V CL=30pF – – 1.6 ns Output Skew SKW1 Measured at VDD/2 and Outputs are equally loaded – 70 150 ps Part to Part Skew SKW2 Measured at VDD/2 and Outputs are equally loaded – 100 200 ps 2.5 3.5 4.5 ns Propagation Delay Time PDT Measured at VDD/2 from CLKIN to Output Clock rising edge and Outputs are equally loaded Cycle-to-Cycle Jitter CCJ1 CLKIN=66MHz and CL=0 (No Load) – 35 70 ps Cycle-to-Cycle Jitter CCJ2 CLKIN=166MHz and CL=0 (No Load) – 25 50 ps DC Electrical Characteristics (I-Grade) Unless otherwise stated VDD= 3.3V+/- 10%, CL=15pF and Ambient Temperature range -40 to +85°C Description Symbol Condition Min Typ Max Unit Input LOW Voltage VINL CLKIN – – 0.8 V Input HIGH Voltage VINH CLKIN 2.0 – VDD+0.3 V Input LOW Current IINL 0 < VIN < 0.8V – – 10 µA Input HIGH Current IINH 2.4V < VIN < VDD – – 15 µA Output Low Voltage VOL IOL=12mA – – 0.4 V Output High Voltage VOH IOH=-12mA 2.4 – – V Power Supply Current IDD1 CLKIN=33.3MHz, CL=0 – 10 14 mA Power Supply Current IDD2 CLKIN=66.6MHz, CL=0 – 12 17 mA Power Supply Current IDD3 CLKIN=133.3MHz, CL=0 – 16 21 mA Switching Electrical Characteristics (I-Grade) Unless otherwise stated VDD= 3.3V+/- 10%, CL=15pF and Ambient Temperature range -40 to +85°C Description Symbol Condition Min Typ Max Unit FOUT1 CL=15pf 0 – 220 MHz FOUT2 CL=30pf 0 – 134 MHz Output Frequency Range Input Duty Cycle DC1 Measured at VDD/2 20 50 80 % Output Duty Cycle DC2 CL=15pF, Fout=166MHz Measured at VDD/2 45 50 55 % Output Duty Cycle DC3 CL=30pF, Fout=100MHz Measured at VDD/2 40 50 60 % Output Rise/Fall Time tr/f-1 Measured at 0.8V to 2.0V, CL=15pF – – 1.4 ns Output Rise/Fall Time tr/f-2 Measured at 0.8V to 2.0V, CL=30pF – – 1.8 ns Rev 2.2, May 6, 2008 Page 5 of 11 SL23EP09NZ Output Skew SKW1 Measured at VDD/2 and Outputs are equally loaded – 80 160 ps Part to Part Skew SKW2 Measured at VDD/2 and Outputs are equally loaded – 110 220 ps 2.0 3.5 4.8 ns Propagation Delay Time PDT Measured at VDD/2 from CLKIN to Output Clock rising edge and Outputs are equally loaded Cycle-to-Cycle Jitter CCJ1 CLKIN=66MHz and CL=0 (No Load) – 40 80 ps Cycle-to-Cycle Jitter CCJ2 CLKIN=133MHz and CL=0 (No Load) – 30 60 ps Min Typ Max Unit 2.25 2.5 2.75 V Operating Conditions (C-Grade and I-Grade) Unless otherwise stated VDD= 2.5V+/- 10%, CL=15pF Description Operating Voltage Symbol Condition VDD VDD+/-10% TA1 Ambient Temperature C-Grade 0 – 70 °C TA2 Ambient Temperature I-Grade -40 – 85 °C VINC Pin 1 – 5 7 pF CL1 All outputs ≤180MHz – – 15 pF CL2 All outputs ≤100MHz – – 30 pF Operating Temperature Input Capacitance Load Capacitance Operating Frequency CLKIN-1 Input Clock Range, CL=15pF DC – 180 MHz Operating Frequency CLKIN-2 Input Clock Range, CL=30pF DC – 80 MHz DC Electrical Characteristics (C-Grade) Unless otherwise stated VDD= 2.5V+/- 10%, CL=15pF and Ambient Temperature range 0 to +70°C Description Symbol Condition Min Typ Max Unit Input LOW Voltage VINL CLKIN – – 0.7 V Input HIGH Voltage VINH CLKIN 1.7 – VDD+0.3 V Input LOW Current IINL 0 < VIN < 0.8V – – 15 µA Input HIGH Current IINH 2.4V < VIN < VDD – – 25 µA Output Low Voltage VOL IOL=8mA – – 0.4 V Output High Voltage VOH IOH=-8mA VDD-0.6 – – V Power Supply Current IDD1 CLKIN=33.3MHz, CL=0 – 9 14 mA Power Supply Current IDD2 CLKIN=66MHz, CL=0 – 11 17 mA Power Supply Current IDD3 CLKIN=166MHz, CL=0 – 15 21 mA Rev 2.2, May 6, 2008 Page 6 of 11 SL23EP09NZ Switching Electrical Characteristics (C-Grade) Unless otherwise stated VDD= 2.5V+/- 10%, CL=15pF and Ambient Temperature range 0 to +70°C Description Symbol Condition Min Typ Max Unit FOUT1 CL=15pf 0 – 180 MHz FOUT2 CL=30pf 0 – 80 MHz Output Frequency Range Input Duty Cycle DC1 Measured at VDD/2 20 50 80 % Output Duty Cycle DC2 CL=15pF, Fout=166MHz Measured at VDD/2 45 50 55 % Output Duty Cycle DC3 CL=30pF, Fout=80MHz Measured at VDD/2 40 50 60 % Output Rise/Fall Time tr/f-1 Measured at 0.6V to 1.8V CL=15pF – – 1.6 ns Output Rise/Fall Time tr/f-2 Measured at 0.6V to 1.8V CL=30pF – – 2.0 ns Output Skew SKW1 Measured at VDD/2 and Outputs are equally loaded – 90 180 ps Part to Part Skew SKW2 Measured at VDD/2 and Outputs are equally loaded – 120 240 ps 3.0 4.0 5.0 ns Propagation Delay Time PDT Measured at VDD/2 from CLKIN to Output Clock rising edge and Outputs are equally loaded Cycle-to-Cycle Jitter CCJ1 CLKIN=66MHz and CL=0 (No Load) – 50 100 ps Cycle-to-Cycle Jitter CCJ2 CLKIN=166MHz and CL=0 (No Load) – 35 70 ps DC Electrical Characteristics (I-Grade) Unless otherwise stated VDD= 2.5V+/- 10%, CL=15pF and Ambient Temperature range -40 to +85°C Description Symbol Condition Min Typ Max Unit Input LOW Voltage VINL CLKIN – – 0.7 V Input HIGH Voltage VINH CLKIN 1.7 – VDD+0.3 V Input LOW Current IINL 0 < VIN < 0.8V – – 15 µA Input HIGH Current IINH 2.4V < VIN < VDD – – 25 µA Output Low Voltage VOL IOL=8mA – – 0.4 V Output High Voltage VOH IOH=-8mA VDD-0.6 – – V Power Supply Current IDD1 CLKIN=33.3MHz, CL=0 – 10 14 mA Power Supply Current IDD2 CLKIN=66.6MHz, CL=0 – 12 17 mA Power Supply Current IDD3 CLKIN=133.3MHz, CL=0 – 16 23 mA Rev 2.2, May 6, 2008 Page 7 of 11 SL23EP09NZ Switching Electrical Characteristics (I-Grade) Unless otherwise stated VDD= 2.5V+/- 10%, CL=15pF and Ambient Temperature range -40 to +85°C Description Symbol Condition Min Typ Max Unit FOUT1 CL=15pf 0 – 180 MHz FOUT2 CL=30pf 0 – 80 MHz Output Frequency Range Input Duty Cycle DC1 Measured at VDD/2 20 50 80 % Output Duty Cycle DC2 CL=15pF, Fout=166MHz Measured at VDD/2 45 50 55 % Output Duty Cycle DC3 CL=30pF, Fout=100MHz Measured at VDD/2 40 50 60 % Output Rise/Fall Time tr/f-1 Measured at 0.8V to 2.0V CL=15pF – – 1.8 ns Output Rise/Fall Time tr/f-2 Measured at 0.8V to 2.0V CL=30pF – – 2.2 ns Output Skew SKW1 Measured at VDD/2 and Outputs are equally loaded – 100 200 ps Part to Part Skew SKW2 Measured at VDD/2 and Outputs are equally loaded – 140 280 ps 2.5 4.0 5.5 ns Propagation Delay Time PDT Measured at VDD/2 from CLKIN to Output Clock rising edge and Outputs are equally loaded Cycle-to-Cycle Jitter CCJ1 CLKIN=66MHz and CL=0 (No Load) – 60 120 ps Cycle-to-Cycle Jitter CCJ2 CLKIN=133MHz and CL=0 (No Load) – 50 100 ps Rev 2.2, May 6, 2008 Page 8 of 11 SL23EP09NZ External Components & Design Considerations Typical Application Schematic BUF_IN 1 OUTPUT1 2 CL 3 SL23EP09NZ VDD OUTPUT2 CL 4,8,13 0.1μF 5,9,12 16 OUTPUT9 CL GND Comments and Recommendations Decoupling Capacitor: A decoupling capacitor of 0.1μF must be used between all VDD and VSS pins. Place the capacitor on the component side of the PCB as close to the VDD pin as possible. The PCB trace to the VDD pin and to the GND via should be kept as short as possible. Do not use vias between the decoupling capacitor and the VDD pin. Series Termination Resistor: A series termination resistor is recommended if the distance between the output clocks and the load is over 1 ½ inch. Place the series termination resistors as close to the clock outputs as possible. Rev 2.2, May 6, 2008 Page 9 of 11 SL23EP09NZ Package Outline and Package Dimensions 16-Lead SOIC (150-Mil) 16 9 Dimensions are in inches (milimeters). Top line: (MIN) and Bottom line: (Max) 0.150(3.810) 0.157(3.987) Pin-1 ID 0.230(5.842) 0.244(6.197) 1 8 0.386(9.804) 0.393(9.982) 0.010(0.2540) X 45° 0.016(0.406) 0.0075(0.190) 0.0098(0.249) 0.061(1.549) 0.068(1.727) 0.004(0.102) 0.050(1.270) BSC 0.004(0.102) 0.0098(0.249) Seating plane 0.016(0.406) 0.035(0.889) 0° to 8° 0.0138(0.350) 0.0192(0.487) Thermal Characteristics Parameter Thermal Resistance Junction to Ambient Thermal Resistance Junction to Case Rev 2.2, May 6, 2008 Symbol Condition Min Typ Max Unit θ JA Still air - 78 - °C/W θ JA 1m/s air flow - 74 - °C/W θ JA 3m/s air flow - 70 - °C/W θ JC Independent of air flow - 44 - °C/W Page 10 of 11 SL23EP09NZ Ordering Information [1] Ordering Number Marking Shipping Package Package Temperature SL23EP09NZSC-1H SL23EP09NZSC-1H Tube 16-pin SOIC 0 to 70°C SL23EP09NZSC-1HT SL23EP09NZSC-1H Tape and Reel 16-pin SOIC 0 to 70°C SL23EP09NZSI-1H SL23EP09NZSI-1H Tube 16-pin SOIC -40 to 85°C SL23EP09NZSI-1HT SL23EP09NZSI-1H Tape and Reel 16-pin SOIC -40 to 85°C Notes: 1. The SL23EP09NZ products are RoHS compliant. The information in this document is believed to be accurate in all respects at the time of publication but is subject to change without notice. Silicon Laboratories assumes no responsibility for errors and omissions, and disclaims responsibility for any consequences resulting from the use of information included herein. Additionally, Silicon Laboratories assumes no responsibility for the functioning of undescribed features or parameters. Silicon Laboratories reserves the right to make changes without further notice. Silicon Laboratories makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does Silicon Laboratories assume any liability arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation consequential or incidental damages. Silicon Laboratories products are not designed, intended, or authorized for use in applications intended to support or sustain life, or for any other application in which the failure of the Silicon Laboratories product could create a situation where personal injury or death may occur. Should Buyer purchase or use Silicon Laboratories products for any such unintended or unauthorized application, Buyer shall indemnify and hold Silicon Laboratories harmless against all claims and damages. Rev 2.2, May 6, 2008 Page 11 of 11 ClockBuilder Pro One-click access to Timing tools, documentation, software, source code libraries & more. Available for Windows and iOS (CBGo only). www.silabs.com/CBPro Timing Portfolio www.silabs.com/timing SW/HW www.silabs.com/CBPro Quality www.silabs.com/quality Support and Community community.silabs.com Disclaimer Silicon Laboratories intends to provide customers with the latest, accurate, and in-depth documentation of all peripherals and modules available for system and software implementers using or intending to use the Silicon Laboratories products. Characterization data, available modules and peripherals, memory sizes and memory addresses refer to each specific device, and "Typical" parameters provided can and do vary in different applications. Application examples described herein are for illustrative purposes only. Silicon Laboratories reserves the right to make changes without further notice and limitation to product information, specifications, and descriptions herein, and does not give warranties as to the accuracy or completeness of the included information. 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