NB3N1900KMNGEVB NB3N1900K Evaluation Board User's Manual Introduction http://onsemi.com The NB3N1900KMNGEVB evaluation boards were developed for the NB3N1900K (HCSL) devices. This evaluation board was designed to provide a flexible and convenient platform to quickly evaluate, characterize and verify the operation of the NB3N1900K devices. This evaluation board manual contains: • Information on the NB3N1900K Evaluation Board • Assembly Instructions • Test and Measurement Setup Procedures • Board Schematic and Bill of Materials This manual should be used in conjunction with the device datasheet which contains full technical details on the device specifications and operation. (Top View) (Bottom View) EVAL BOARD USER’S MANUAL Figure 1. NB3N1900KMNGEVB Evaluation Board © Semiconductor Components Industries, LLC, 2014 October, 2014 − Rev. 1 1 Publication Order Number: EVBUM2256/D NB3N1900KMNGEVB BOARD FEATURES • All Layers are Constructed with FR4 Dielectric Single Board Design/Layout • Accommodates the Electrical Characterization of the • • • • Material • The First Layer is the Primary Signal Layer, Including NB3N1900K (HCSL Outputs) Incorporates On-board I2C/SMBus Interface Circuitry Powered from a USB Connection, Minimizing Cabling Convenient and Compact Board Layout 3.3 V Power Supply Device Operation Differential Inputs/Outputs Signals are Accessed via SMA Connectors or High Impedance Probes • • • Other Board Features There are no vias on the high-speed differential I/O metal traces so as to eliminate via impedance and stub affects. Board stand-offs are installed. All of the Differential Inputs and Outputs The Second Layer is the Ground Plane. It is Dedicated for the DUT Ground/SMA Ground Plane The Third Layer is Dedicated as the Power Plane. A Portion of this 3rd Layer is Designated for the Device VDD and VDDIO Power Planes The Fourth Layer Contains Control Lines, Power Supply Banana Jacks and Device Power Pin By-pass Capacitors Layer Stack L1 (Top) Signal L2 Device Ground and SMA Ground L3 VDD, VDDIO (Separate Device Power Supplies) L4 (Bottom), Power Supply By-pass Capacitors, Control Pin Traces and Banana Jacks • • • • Board Layout The NB3N1900K QFN−72 Evaluation Board provides a high bandwidth, 50-W controlled trace impedance environment (100-W line-to-line differential) and is implemented in four layers. Figure 2. NB3N1900KMNGEVB Evaluation Board Layer Stack-Up Power Supplies Board Layer #3 = VDD and VDDIO Power Supplies VDD = positive power supply for core and inputs; VDD/VDDA/VDDR (pins #1, 8) VDDIO = positive power supply for outputs; VDDIO (pins #21, 31, 45, 58, 68) Each VDD, VDDIO and GND power supply has a separate side-launch banana jack located on bottom side. This board is capable of measuring device IDD & IDDIO separately. Board Layer #2 = SMA Ground = Device GND = 0 V. GND Banana Jack = negative power supply for DUTGND and SMAGND. VDD & VDDIO have the power supply filtering per datasheet by the banana jacks. All VDD/VDDA/VDDR/VDDIO device pins have a 0.1 mF bypass capacitor installed on top side next to package pins. Exposed Pad (EP): The exposed pad footprint on the board is soldered to the exposed pad of the QFN−72 package, and is electrically connected to GND power supply. http://onsemi.com 2 NB3N1900KMNGEVB • For a HIGH Level – Put Jumper to High • For a LOW Level − Put Jumper to Low • For a MID Level − Put Jumper to both High and Low; Control Pins Each control pin can be managed manually with a H/L jumper header; H = VDD, L = GND. this will Enable both Pull-up and Pull-down Resistors Tri-Level Input Pins − HBW_BYP_LBW#, SA_0 and SA_1 The three tri-level input pins, HBW_BYPASS_LBW#, SA0 and SA1, have selectable (with jumper) 4.7 kW pull-up to VDD and 4.7 kW pull-down to GND resistors; No jumper defaults to open/float. HBW_BYP_LBW# At J16 header, there is a 4.7 kW pull-up to VDD and a 4.7 kW pull-down resistor to GND for manual control. Figure 3. HBW_BYP_LBW# Schematic Configuration SA_0 & SA_1 At J21 and J23 headers, there are 4.7 kW pull-ups to VDD and 4.7 kW pull-down resistors to GND for manual control. Figure 4. SA_0 & SA_1 Schematic Configuration OE_n# Pins (Output Enable/Disable Function) Four of the eight differential outputs can be controlled manually using the convenient High/Low OE_n# jumpers. See Figure 5. All eight of the OE_n#s can be controlled individually/ automatically by using the software GUI. GUI control is accomplished via the USB. See Figure 5. http://onsemi.com 3 NB3N1900KMNGEVB Figure 5. OE_n# Pins Schematic Configuration 100M_133M# − Frequency Selection (J18) The 100M_133M# frequency selection pin can be controlled manually with the High/Low header jumper J18, H = 100 MHz, L = 133 MHz. Figure 6. 100M_133M# Pin Schematic Configuration PWRGD/PWRDN# (J19) The PWRGD/PWRDN# pin can be controlled manually with the High/Low header jumper J19; H = PWRGD, L = PWRDN#. Figure 7. PWRGD/PWRDN# Pin Schematic Configuration http://onsemi.com 4 NB3N1900KMNGEVB Differential Clock Inputs and Outputs Six of the nineteen differential outputs are designed to have equal length metal traces from the device pins to the SMA connectors. The other thirteen differential outputs have shortened metal traces, do not have SMA connectors and can be observed with a high-impedance probe on the metal pads provided. Each DIF_n/DIF_n# output has a provision for CLoad; 2 pF capacitors are installed on all outputs. RS & RP pads are located close to the DUT. RS = 33-W is installed for the NB3N1900K. NB3N1900K (HCSL Outputs): RP can be uninstalled on the six output pair with long metal traces to SMA connectors; Use 50-W to GND of the oscilloscope head for RP. CLK_IN & CLK_IN# − Differential Clock Inputs The differential Clock input traces, CLK_IN/CLK_IN#, are equal length routed straight from the SMA connectors on the left side directly to the DUT; there are no vias on metal traces. CLK_IN & CLK_IN# have resistor pads (R63 & R64) to GND to terminate a signal generator, if used. 50-W resistors are installed. Remove these resistors if CLK_IN & CLK_IN# are driven by another IC device. DIF_n and DIF_n# − Differential Outputs NB3N1900KMNGEVB were designed to measure the differential HCSL outputs with a 50-W scope head or high-impedance FET probe. (See Output Schematic in Figure 8) RP is installed (50-W to GND) on the short metal traces without SMA connectors and will use Hi-Z probes. Table 1. NB3N1900KMNGEVB OUTPUT LOAD AND TERMINATION VS. OSCILLOSCOPE MEASUREMENT Device Output Traces RS RP CLoad Scope 1900K Long (1.5″) 33-W Open (DNI) or 50-W 2 pF 50-W or Hi-Z 1900K Short 33-W 50-W 2 pF Hi-Z Figure 8. Differential Outputs Schematic Configuration: Long (OUT6) vs. Short (OUT7) Metal Traces HCSL Output Measurement Misc. Pins HCSL outputs are typically terminated with 50-W to ground. Measuring HCSL outputs can be easily accomplished by: FB_OUT & FB_OUT# − External Termination of Feedback Pins FB_OUT & FB_OUT# have convenient “test point anvils” to monitor these pins with Hi-Z probe. NB3N1900K (HCSL): Since the FB_OUT & FB_OUT# pins do not drive transmission lines (no SMAs), the board layout has these pins loaded/terminated at the DUT per datasheet; 83-W to GND is installed for the 100-W board. NB3N1900K (HCSL Outputs) − 50-W Oscilloscope Head With RP removed from board, connect the HCSL outputs through the SMA connectors to the 50-W internal impedance of the oscilloscope sampling head. NB3N1900K (HCSL Outputs) − Use Hi-Z Probe With RP installed, use a high-impedance probe on the output’s metal trace. Holes for headers to connect to Hi-Z probes are available, but the header pins are not installed. • Single-ended Hi-Z Probes or, • Differential Hi-Z Probe; IREF Pin NB3N1900K (HCSL): The RREF resistor (R99) to GND is for the HCSL output part device. RREF = 475-W is installed for the 100-W board. http://onsemi.com 5 NB3N1900KMNGEVB In order to enable the I2C control of the DUT, header jumpers J27 & J28 must be shorted. The I2C/SMBus interface circuitry is powered separately from the USB type-B connection and is isolated from device VDD and VDDIO. The SDA and SCL pins can also be externally accessed by an off-board programmer, allowing other SMBus emulators to be used to program the DUT. If used, remove both jumpers J27 & J28. “Test-point anvils” TP33 & TP34 are available for external control of the device with the use with mini-grabber cables. To receive the GUI software and GUI software manual please contact below: Graphical User Interface (GUI) USB & I 2C/SMBus Interface The NB3N1900K EVB has an on-board I2C/SMBus interface circuitry located in the upper left section of the board. This circuitry will interface with the software program and the device via the SDA and SCL input pins, and can control all twelve of the OE_n# pins, PLL Mode and Frequency Select directly from the GUI. SCL & SDA The SMBus Clock (SCL) and Data (SDA) pins are exercised through the on-board I2C interface. http://onsemi.com 6 NB3N1900KMNGEVB QUICK START LAB SET-UP USER’S GUIDE Pre-Power-Up Table 2. POWER SUPPLY CONNECTIONS 1. Connect power supply cables to VDD, VDDIO and GND banana jacks; (do not turn power on, yet). 2. Connect a signal generator to the SMA connectors for the CLK_IN & CLK_IN# inputs. 3. 50-W termination resistors are installed for a signal generator on the board. Set appropriate input signal levels; (HCSL input, VIL = 0 V, VIH = 700 mV, Frequency 100.00 or 133.33 MHz). 4. Ensure the PWRGD/PWRDN# pin is in the Low state before power up (PWRDN#). There is a jumper on pin 6 to easily select between High and Low. See Figure 7. 5. The 100M_133M# and HBW_BYP_LBW pins need to be hardware selected with jumpers. See Figures 3 and 6. 6. Connect the DIF_n/DIF_n# outputs to the appropriate oscilloscope. Device Pin Power Supply Connector Power Supply VDD, VDDIO VCC = +3.3 V GND 0V Single Power Supply +3.3 V 0V VDD, VDDIO +3.3 V GND Figure 9. Power Supply Connections Signal Generator Oscilloscope OUT OUTb IN 0V 3.3 V 3.3 V INb Figure 10. Typical Lab Test Set-Up Power-Up Sequence Optional 1. Turn on power supply, 3.3 V (VDD & VDDIO) 2. Move PWRGD/PWRDN# jumper from Low to logic High, PWRGD position 3. Turn on the Differential Clock Signal for the CLK_IN inputs 4. Monitor DIF_n/DIF_n# outputs on oscilloscope Graphical User Interface There is a stand-alone Graphical User Interface software package and user’s manual that will interface with the DUT via the USB connector. 1. Connect the USB port on the evaluation board to a USB port on the PC via cable. 2. See the stand-alone GUI instructions document. 3. Allow Windows to install the necessary drivers for the eval board USB interface hardware. 4. Start the GUI program. http://onsemi.com 7 NB3N1900KMNGEVB Table 3. BILL OF MATERIALS FOR THE NB3N1900KMNGEVB Ref. Des. Qty Part# Value B1 1 C1−C35, C37, C42, C43 38 C1005C0G1H020C 2.0 pF C36, C44 2 TR3A106K010C2000 C38, C40, C67, C68 4 C39, C41, C46−C54, C56−C58, C60, C62, C65, C69 PCB Footprint Vendor Vendor PN HiQ Electronics NB3N1900KMNGEVB C0402 Digi-Key 445-4863-1-ND TDK 10 mF C1206 Digi-Key 718-1300-1-ND Vishay GRM155R61A105ME15D 1 mF C0402 Digi-Key 490-5409-1-ND Murata 18 0402ZD104KAT2A 100 nF C0402 Digi-Key 478-1129-1-ND AVX PC Board, Clock Fanout Board Manufacturer C45 1 C1608X5R1A106M 10 mF C0603 Digi-Key 445-6853-1-ND TDK C55, C59, C61 3 C1005X5R0J475M 4.7 mF C0402 Digi-Key 445-7395-1-ND TDK C63 1 0402YC103KAT2A 10 nF C0402 Digi-Key 478-1114-1-ND AVX C64, C66 2 GRM1555C1H100JZ01D 10 pF C0402 Digi-Key 490-1278-1-ND Murata D1 1 PACDN004SR PACDN004 SOT_143 Mouser 748-PACDN004SR ON Semiconductor FB1, FB2 2 BLM18KG601SN1D 600 L0603 Digi-Key 490-5258-1-ND Murata FB3, FB4 2 BLM15AG601SN1D 600 L0402 Digi-Key 490-1006-1-ND Murata H1, H2, H3, H4 4 .129 Hole in .240 Round Pad HOLE_0.240R0.12 9_PTH J1−J4, J6, J7, J10, J11, J13, J14, J15, J17, J20, J22 14 142-0701-801 SMA Jack, End Launch SMA_Jack_End_L aunch Digi-key J502-ND Johnson Components J5, J8, J9, J12, J16, J18, J19, J21, J23 9 961103-6404-AR Header 3-pin HDR_1X3_2P54 Digi-Key 3M9448-ND 3M J24 1 571-0500 Banana Jack, Thru-Hole, Red con_571-0500 Mouser 164-6219 Deltron J25 1 571-0700 Banana Jack, Thru-Hole, Yellow con_571-0500 Mouser 164-7170 Deltron J26 1 571-0100 Banana Jack, Thru-Hole, Black con_571-0500 Mouser 164-6218 Deltron J27, J28 2 961102-6404-AR Header 2-pin HDR_1X2_2P54 Digi-Key 3M9447-ND 3M J29 1 USB-B1SMHSW6 Conn, USB−B, SMT Con_USB_B_RA Digi-Key ED2994-ND On Shore Technology LED_0603 LED1 1 LTST-C190KGKT LED, Green Digi-Key 160-1435-1-ND Lite-On M1−M8, M10 9 QPC02SXGN-RC Shunt Digi-Key S9337-ND Sullins M9, M11−M13 4 1808 Standoff, 4−40 1/4 × 5/8 Digi-Key 1808K-ND Keystone M14−M17 4 PMS 440 0025 PH Screw, 4−40 × 0.25, PHP Digi-Key H342-ND Building Fasteners PR1−PR6 6 No Part 4 Round Pads, .060 with .040 Hole BERG_2X2_2P54 http://onsemi.com 8 NB3N1900KMNGEVB Table 3. BILL OF MATERIALS FOR THE NB3N1900KMNGEVB (continued) Ref. Des. Qty R1, R2, R5, R6, R10, R11, R14, R18, R19, R22, R25, R27, R30, R31, R32, R34, R37, R39, R41, R43, R45, R48, R51, R53, R55, R58, R61, R65, R69, R72, R75, R77, R79, R83, R88, R92, R95, R97 Part# Value PCB Footprint Vendor Vendor PN Manufacturer 38 33 W R0402 Digi-Key P33JTR-ND Panasonic R3, R7, R16, R20, R23, R28, R33, R35 8 49.9 W R0402 Digi-Key P49.9LCT-ND Panasonic R4, R8, R17, R21, R24, R26, R29, R36, R38, R40, R42, R44, R47, R50, R52, R54, R57, R60, R62, R66, R71, R74, R76, R78, R82, R87, R90, R94, R96, R98 30 49.9 W R0402 Digi-Key P49.9LCT-ND Panasonic R9, R12, R13, R15, R46, R49, R56, R59, R70, R73, R80, R84 12 CRCW04020000Z0ED 0W R0402 Digi-Key 541-0.0JCT-ND Vishay R63, R64 2 ERJ-3EKF49R9V 49.9 W R0603 Digi-Key P49.9HCT-ND Panasonic R67, R68, R85, R89 4 ERJ-3GEYJ472V 4.7 kW R0603 Digi-Key P4.7KGCT-ND Panasonic R81, R86 2 ERJ-3GEYJ472V 4.7 kW R0603 Dig-Key P4.7KGCT-ND Panasonic R91, R93 2 ERJ-3GEYJ2R2V 2.2 W R0603 Digi-Key P2.2GCT-ND Panasonic R99 1 ERJ-2RKF4120X 475 W R0402 Digi-Key P412LCT-ND Panasonic R100, R102 2 ERJ-2GE0R00X 0W R0402 Digi-Key P0.0JCT-ND Panasonic R101, R103 2 ERJ-2RKF69R8X 82.5 W R0402 Digi-Key P69.8LCT-ND Panasonic R104−R106, R108−R110 6 ERJ-2GEJ103X 10 kW R0402 Digi-Key P10KJCT-ND Panasonic R107 1 ERJ-2RKF1202X 12 kW R0402 Digi-Key P12.0KLCT-ND Panasonic R111 1 ERJ-2GEJ471X 470 W R0402 Digi-Key P470JCT-ND Panasonic R112 1 ERJ-2GEJ222X 2.2 kW R0402 Digi-Key P2.2KJCT-ND Panasonic SG1−SG12 12 No Part Solder Gap R0201 TP1−TP22, TP24, TP26, TP28, TP29 26 Test Pad 30 × 30 mil tp_30_30 TP23, TP25, TP27, TP30−TP34 8 5015 Test Point, SMT tp_70_135 Digi-Key 5015KCT-ND Keystone TP35, TP36 2 No Part Test Pad 30 × 60 mil tp_30_60 TP37−TP40 4 No Part Test Pad 50 × 100 mil tp_50_100 U1 1 NB3N1900KMNG DNI NB3N1900K QFN_72P_0P5MM − − ON Semiconductor http://onsemi.com 9 NB3N1900KMNGEVB Table 3. BILL OF MATERIALS FOR THE NB3N1900KMNGEVB (continued) Ref. Des. Qty Part# Value PCB Footprint Vendor U2 1 FT2232HQ-REEL U3 1 93LC46BT-I/ST U4 1 Y1 1 Vendor PN Manufacturer FT2232H QFN_64_0p5 Digi-Key 768-1025-1-ND FTDI 93LC46B TSSOP_8_4p4W_ 0P65 Digi-Key 93LC46BT-I/STCT-ND Microchip NCP4586DSN33T1G NCP4586, 3.3 V SOT23_5p ON Semiconductor NCP4586DSN33T1G ON Semiconductor ABM8G-12.000MHZ-4Y-T3 12 MHz Cry-4p-SMD1 Digi-Key 535-10901-1-ND Abracon Corp ON Semiconductor and the are registered trademarks of Semiconductor Components Industries, LLC (SCILLC) or its subsidiaries in the United States and/or other countries. SCILLC owns the rights to a number of patents, trademarks, copyrights, trade secrets, and other intellectual property. A listing of SCILLC’s product/patent coverage may be accessed at www.onsemi.com/site/pdf/Patent−Marking.pdf. SCILLC reserves the right to make changes without further notice to any products herein. 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