NB3H83905CDGEVB NB3H83905CDGEVB Evaluation Board User's Manual http://onsemi.com EVAL BOARD USER’S MANUAL Device Description Board Features • Crystal source mount, or external clock source (SMA) The NB3H83905CDG device is a 1.8 V, 2.5 V or 3.3 V VDD core Crystal input 1:6 LVTTL/LVCMOS fanout buffer with outputs powered by flexible 1.8 V, 2.5 V, or 3.3 V supply (with VDDwVDDO). The core inputs accept a fundamental Parallel Resonant crystal from 3 MHz to 40 MHz or Single Ended LVCMOS Clock from 3 MHz to 100 MHz. Core supply must be equal or greater voltage than the output supply. See datasheet NB3H83905C/D (www.onsemi.com). • • Evaluation Board Description input. One 25 Mhz crystal is supplied. A SOIC−16 NB3H83905CDG device is solder mounted. The board may be adapted for insertion testing by removing the device and adding a 16 Lead SOIC socket (M&M #50−000−00112) Separate supply connectors for VDD, VDDO, SMAGND, and DUTGND (banana jacks and anvil clips) Contents The NB3H83905CDGEVB Evaluation board is designed to provide a flexible and convenient platform to quickly program, evaluate and verify the performance and operation of the NB3H83905CDG SOIC−16 device under test. With the device removed, this NB3H83905CDGEVB Evaluation board is designed to accept a 16 Lead SOIC socket (M&M Specialties, Inc., 1−800−892−8760, www.mmspec.com, M&M #50−000−00112) to permit use as an insertion test fixture. Descriptions Board Features Board Layout Maps Test and Measurement Setup Procedures Appendix 1: Pin to Board Connection Information Appendix 2: Board Top and Bottom Layer Designs Appendix 3: Bill of Materials, Lamination Stackup FRONT BACK Figure 1. NB3H83905CDGEVB Evaluation Board © Semiconductor Components Industries, LLC, 2012 February, 2012 − Rev. 1 1 Publication Order Number: EVBUM2061/D NB3H83905CDGEVB Board Layout Maps VDD ANVIL Connector XTALIN SMA EN1 SMA EN2 SMA DUTGND ANVIL Connector VDD CAP C8 BCLK5 BCLK0 BCLK4 BCLK1 VDDO ANVIL Connector SMAGND ANVIL Connector BCLK3 BCLK2 Figure 2. FRONT XTALOUT Crystal Mount XTALIN Crystal Mount DUTGND Connector VDD Connector VDDO Connector SMAGND Connector Figure 3. BACK http://onsemi.com 2 NB3H83905CDGEVB TEST AND MEASUREMENT SET−UP AND PROCEDURE Step 2: Lab Set−Up Procedure (Split Supplies into LOW impedance 50 Ohm equipment or probes) 1) Test Supply Setup: VDDO and GND Supplies may be centered on 0.0 V to permit direct connection to an Oscilloscope module (with 50 Ohm to GND) per Figure 4 and Table 1. Connect all board supplies using banana jack or clip anvil. Step 1: Equipment 1.) Signal Generator: Agilent #33250A or HP8133 (or equivalent) 2.) Tektronix TDS8000 Oscilloscope 3.) Power Supply: Agilent #6624A or AG6626A DC (or equivalent) 4.) Digital Voltmeter: Agilent 34410A or 34401 (or equivalent) 5.) Matched Cables (> 20 GHz, SMA connectors): Storm or Semflex (or equivalent) 6.) Time Transition Convertor: Agilent 14534 250 ps (or equivalent) 7.) Phase noise Analyzer: Agilent E5052B (or equivalent) Figure 4. Typical Device Termination Setup and Termination Test Setup Table 1. Test Voltages Datasheet Spec Condition TEST SETUP VDD TEST SETUP VDDO TEST SETUP DUT GND VDD = VDDO = 3.135 V to 3.465 V (3.3 V Nom. ±5%) 1.56 to 1.73 V 1.56 to 1.73 V −1.56 to −1.73 V VDD = VDDO = 2.375 V to 2.625 V (2.5 V Nom. ±5%) 1.1875 to 1.3125 V 1.1875 to 1.3125 V −1.1875 to −1.3125 V VDD = VDDO = 1.6 V to 2.0 V (1.8 V Nom. ±0.2 V) 0.8 to 1.0 V 0.8 to 1.0 V −0.8 to −1.0 V VDD = 3.135 V to 3.465 V (3.3 V Nom.); VDDO =2.375 V to 2.625 V (2.5 V Nom.) 1.955 to 2.1525 V 1.1875 to 1.3125 V −1.1875 to −1.3125 V VDD=3.135 V to 3.465 V (3.3 V Nom.); VDDO=1.6 V to 2.0 V (1.8 V Nom.) 2.335 to 2.465 V 0.8 to 1.0 V −0.8 to −1.0 V VDD=2.375 V to 2.625 V (2.5 V Nom.); VDDO=1.6 V to 2.0 V (1.8 V Nom.) 1.575 to 1.625 0.8 to 1.0 V −0.8 to −1.0 V 2.) Inputs: For a Single Ended operation, bridge the small gap in located at the device footprint outline in the trace line to the SMA connector XTALIN. Use a LVCMOS Clock amplitude signal from 3 MHz to 100 MHz on the XTAL_IN/CLK pin16. Note the levels must be shifted according to the http://onsemi.com 3 NB3H83905CDGEVB capacitance CL = 18 pF would use C1 = 15 pF and C2 = 15 pF as initial values. These values may be adjusted to fine tune frequency accuracy. Increasing the C1 and C2 values will reduce the operational frequency. Enable 1 and 2 (see Datasheet Table 2) levels must be shifted according to the supply voltages. Open default condition will force a HIGH (enabled) due to an internal pullup resistor to VCC. 3.) Outputs: Connect LVCMOS outputs to the oscilloscope with matched cables. NOTE: THE READINGS OF THE OUTPUT VOLTAGE LEVELS WILL BE OFFSET. With this split supply, the device outputs will be parallel terminated by the oscilloscope (or frequency counter) input module’s internal 50 Ohms to GND impedance. supply voltages. Transitions Edges should about 250 ps or use TTC, Time transition Convertor, such as Agilent 14534 (250 ps) or an equivalent. Do not drive XTALOUT. Termination of the signal generator may be needed with 50 Ohms to SMA ground. For Crystal operation use a fundamental Parallel Resonant crystal (see Datasheet Table 3) from 3 MHz to 40 MHz across pins 1 and 16. The Crystal mount is located on the back of the board and permanently connected to the device inputs by traces. Crystal Load capacitance (C1 and C2) values should consider all parasitic capacitances. Datasheet Figure 1 shows the typical NB3H83905C device crystal interface using a parallel resonant crystal. The frequency accuracy can be fine tuned by adjusting the C1 and C2 values. For example, a parallel crystal with loading APPENDIX 1: DEVICE PIN TO BOARD CONNECTION INFORMATION (see current Datasheet) Table 2. Device Pins to Board Connection Device Pin Board Name I/O Description 1 XTAL_OUT Crystal Interface Oscillator Output to drive Crystal 2 ENABLE 2 LVTTL / LVCMOS Input Synchronous Enable Input for BCLK5 Output. Switches only when HIGH. Open default condition HIGH due to an internal pullup resistor to VCC. Connection 3, 7, 11 DUTGND or DUTGND_TP GND GND GND Supply pins. All VDD and VDDO pins must be externally connected to power supply to guarantee proper operation. 4, 6, 8, 10, 12, 14 BCLK0, 1, 2, 3, 4, 5 BCLK0, 1, 2, 3, 4, 5 LVCMOS Outputs Buffered Clock outputs 5, 13 VDDO VDDO POWER Output Positive Supply pins. All VDD and VDDO pins must be externally connected to power supply to guarantee proper operation. Bypass with 0.01 mF cap to GND. 9 VDD or VDD_TP VDD POWER Output Positive Supply pins. All VDD and VDDO pins must be externally connected to power supply to guarantee proper operation. Bypass with 0.01 mF cap to GND. 15 EN1 ENABLE 1 LVTTL / LVCMOS Input Synchronous Enable Input for BCLK0/1/2/3/4 Output block. Switches only when HIGH. Open default condition HIGH due to an internal pullup resistor to VCC 16 XTALIN XTAL_IN/ CLK Crystal Interface Oscillator Input from Crystal. Single ended Clock Input. SMAGND or SMAGND_TP SMAGND SMA connectors GND. Should be connected equipment GND. http://onsemi.com 4 NB3H83905CDGEVB APPENDIX 2: BOARD TOP AND BOTTOM LAYER DESIGNS Figure 5. Top Layer Design http://onsemi.com 5 NB3H83905CDGEVB Figure 6. Bottom Layer Design http://onsemi.com 6 NB3H83905CDGEVB APPENDIX 3: BILL OF MATERIALS, LAMINATION STACKUP, AND ASSEMBLY NOTES Components Mfr / Part No. Description Supplier / Part Number Qty BANANA1 VDD, VDDO Deltron / 579-0500 Connector, Banana Jack Mouser / #164-6219 2 BANANA2 DUT GND, SMA GND Deltron / 579-0500 Connector, Banana Jack, Deltron, Black #571-0500 Mouser / #164-6218 1 BANANA3 SMA GND Deltron / 579-0500 Connector, Banana Jack, Deltron, Green #571-0500 Mouser / #164-7140 1 C4, C5, C6, C7, C8, C9 Kemet / C0805C104K5RACTU Cap, Chip, 0.1 mF, 0805, 50V, 10% Digi-Key / 399-1170-1-ND 6 C10, C11 Kemet / T491D226K016AS Cap, Chip, 22 mF, 10% Mouser / 80-T491D226K016AS 2 C1, C2 Kemet / C0805C150J1GACTU Cap, Chip, 15 pF, 10% Mouser / 80-C0805C150J1G 2 J1-J10 Johnson / #142-0711-821 PCB SMA Connector, SMA, Edge Mount Mouser / 530-142-0711-821 2 JMP1, JMP2 SPC TECHNOLOGY / SPC20481 Header, Single Row, Pitch Spacing: 2.54 mm Newark / 93K5734 2 Jumper Block Shunt SPC TECHNOLOGY / SPC19808 Jumper, Pitch Spacing: 2.54 mm Newark / 84K8570 2 SOCKET (OPT.) M&M SOIC-16 Direct Contact XTAL Abracon / ABL−25.000MHZ− B2F 25 Mhz Through Hole AT Cut Fundamental Crystal Newark / 13J1637 1 XTAL Pin Mill-Max crystal pin receptacle / connector #0462-0-15-15-11-27-04-0 2 Rx Bourns / CR0603-J/-000ELF Resistor, Chip, 0 W, 0603, 1/10 W, 1% Mouser/652-CR0603-J/-000ELF 6 Lamination Stack 01 02 03 04 Top Metal SMAGND VDD / DUTGND Bottom Metal http://onsemi.com 7 (1) NB3H83905CDGEVB ON Semiconductor and are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC reserves the right to make changes without further notice to any products herein. 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