AD8175-EVALZ/AD8176-EVALZ/ AD8177-EVALZ/AD8178-EVALZ User Guide UG-890
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AD8175-EVALZ/AD8176-EVALZ/ AD8177-EVALZ/AD8178-EVALZ User Guide UG-890 One Technology Way • P.O. Box 9106 • Norwood, MA 02062-9106, U.S.A. • Tel: 781.329.4700 • Fax: 781.461.3113 • www.analog.com Evaluation Board for the AD8175/AD8176/AD8177/AD8178 Triple Video Crosspoint Switches FEATURES GENERAL DESCRIPTION Full-featured evaluation board for the AD8175/AD8176/AD8177/AD8178 Supports both single-ended and differential input and output Supports RGBHV signal Drives SMA and CAT5 cables Decoded HV sync outputs available Single +5 V or dual ±2.5 V operation The AD8175 and AD8176 are high speed, triple 16 × 9 video crosspoint switch matrixes with a gain of 2 and 4, respectively. Both the AD8175 and AD8176 support 1600 × 1200 RGB displays at a 85 Hz refresh rate. The AD8175 has a 500 MHz bandwidth, 1800 V/μs slew rate, −88 dB crosstalk, and −94 dB isolation (at 5 MHz). The AD8176 has a 450 MHz bandwidth, 1650 V/μs slew rate, −82 dB crosstalk, and −90 dB isolation (at 5 MHz). The AD8177 and AD8178 have the same specifications as the AD8175 and AD8176, respectively, but are 16 × 5 video crosspoint switch matrixes. EVALUATION KIT CONTENTS AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/ AD8178-EVALZ evaluation board Instruction guide for user guide and software download EQUIPMENT NEEDED Signal source or video pattern generator and signal analyzer Power supplies (5 V with 3 A and ±2.5 V with 3 A) SMA to SMA connector for inputs and outputs Male VGA to male VGA connector for inputs and female VGA to male VGA connector for outputs CAT5 cable Workstation or desktop with Windows XP operating system The AD8175, AD8176, AD8177, and AD8178 support two modes of operation: differential in to differential out mode with sync on common-mode (CM) signaling passed through the switch, and differential in to differential out mode with CM signaling removed through the switch. The output CM and black level can be conveniently set via external pins. The outputs can be single ended in conjunction with decoded H and V outputs to drive a monitor directly. The independent output buffers of the AD8175, AD8176, AD8177, and AD8178 can be placed into a high impedance state to create larger arrays by paralleling the crosspoint outputs. The inputs can also be paralleled. The AD8175, AD8176, AD8177, and AD8178 offer both serial and parallel programming modes. The AD8175/AD8176/AD8177/AD8178 are packaged in a fully populated, 26 × 16 ball PBGA package and are available over the extended industrial temperature range of −40°C to +85°C. This user guide provides all of the supporting documents for evaluating the AD8175/AD8176/AD8177/AD8178 using the AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178EVALZ evaluation board. Additional information is available in the AD8175, AD8176, AD8177, and AD8178 data sheets, which should be consulted in conjunction with this user guide when working with the evaluation board. PLEASE SEE THE LAST PAGE FOR AN IMPORTANT WARNING AND LEGAL TERMS AND CONDITIONS. Rev. 0 | Page 1 of 33 UG-890 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide TABLE OF CONTENTS Features .............................................................................................. 1 Outputs ...........................................................................................4 Evaluation Kit Contents ................................................................... 1 NI USB-6501 ..................................................................................5 Equipment Needed ........................................................................... 1 General Description ......................................................................... 1 VBLK, CMENC, VOCM_CMENCOFF, and VOCM_CMENCON Logic Inputs .............................................5 Revision History ............................................................................... 2 Calibration Path.............................................................................5 Evaluation Board Photograph and Block Diagram...................... 3 Quick Start Guide ..............................................................................6 Evaluation Board Hardware ............................................................ 4 Evaluation Board Schematics and Artwork ...................................8 Introduction .................................................................................. 4 Ordering Information .................................................................... 31 Power Supply ................................................................................. 4 Bill of Materials ........................................................................... 31 Inputs ............................................................................................. 4 REVISION HISTORY 10/15—Revision 0: Initial Version Rev. 0 | Page 2 of 33 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide UG-890 EVALUATION BOARD PHOTOGRAPH AND BLOCK DIAGRAM D0 D1 D2 D3 D4 VPOS VNEG VDD DGND AD8175 A0 A1 A2 SERIN A3 SER/PAR WE 1 CLK 0 45-BIT SHIFT REGISTER WITH 5-BIT PARALLEL LOADING SEROUT UPDATE SET INDIVIDUAL, OR RESET ALL OUTPUTS TO OFF 45 CS PARALLEL LATCH RST CMENC 45 9 DECODE 9 × 5:16 DECODERS INPUT RECEIVER G = +1 R G B 144 OUTPUT BUFFER G = +1 2 2 2 2 2 2 R G B R G B 2 V 9 × RGB, HV CHANNELS SWITCH MATRIX G = +2 ENABLE/DISABLE 16 × RGB CHANNELS H 2 2 2 2 2 R G B H VBLK Figure 1. Evaluation Board Photograph and Block Diagram Rev. 0 | Page 3 of 33 VOCM_CMENCON VOCM_CMENCOFF 13649-001 V UG-890 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide EVALUATION BOARD HARDWARE INTRODUCTION Figure 13 shows the schematic of Input 8 to Input 11. The AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/ AD8178-EVALZ evaluation board allows the user to easily evaluate the AD8175/AD8176/AD8177/AD8178 in both the 50 Ω and 75 Ω controlled impedance applications. Figure 3 shows the typical bench setup used to evaluate the 16 × 5 and 16 × 9 crosspoint switch matrixes. IN12 and IN13 Table 1. Device Options IN14 and IN15 Device AD8175 AD8176 AD8177 AD8178 Gain (Differential to Differential) 2 4 2 4 Frequency 500 MHz 450 MHz 500 MHz 450 MHz Switch Matrix 16 × 9 16 × 9 16 × 5 16 × 5 POWER SUPPLY This evaluation board can be used for a single 5 V supply (and ground); dual or split supplies of ±2.5 V, +3 V/−2 V; or other combinations where the voltage difference is 5 V. There are various jumpers on the board to select the different power supply operations. Figure 26 shows the power supply schematic. INPUTS IN0 to IN3 The first four inputs (IN0 to IN3) accept a standard RGBHV output from a PC (sometimes referred to as VGA, but it can be any resolution). The AD8175, AD8176, AD8177, or AD8178 do not directly accept the H and V sync signals as inputs. However, these signals can be carried on the common-mode of differential RGB inputs. A single device, the AD8134 converts the single-ended RGB signals to differential and encodes the H and V sync on the common mode. The IN0 through IN3 inputs each contain an AD8134 in the circuit path to perform this conversion and then drive the inputs to the AD8175/AD8176/AD8177/AD8178. Figure 5 to Figure 8 show the schematics of Input 0 to Input 3. IN4 to IN7 IN4 through IN7 have offset circuits for the differential inputs in addition to the AD8134 circuit that appears on IN0 through IN3. This offset circuit compensates the other half of a differential output if a single-ended output is used. IN4 through IN7 can also accept an RGBHV signal. Figure 9 to Figure 12 show the schematics of Input 4 to Input 7. IN8 to IN11 IN8 through IN11 have RJ45 connectors used to connect a standard Category 5 (CAT5) cable. An AD8134-EVALZ evaluation board can be used at the server end to convert the RGBHV output of the server to differential RGB with sync on common mode. A CAT5 cable can connect the output of the AD8134-EVALZ evaluation board to one of these inputs. IN12 and IN13 have SMA connectors for each polarity of the RGB input for a total of six separate SMA connectors, which can be used to connect to test equipment that is not directly related to PC graphic signals or CAT5-based signals. Figure 14 shows the schematic of Input 12 and Input 13. IN14 and IN15 have ganged, high speed coaxial connectors produced by W. L. Gore, which are used by various Analog Devices, Inc., test systems to enable rapid connector rearrangements of many circuits. These connectors are available for the AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/ AD8178-EVALZ evaluation board to provide ports that are compatible with these test systems. Figure 15 shows the schematics of Input 14 and Input 15. OUTPUTS OUT0 to OUT2 The OUT0 to OUT2 outputs provide single-ended RGB and H and V signals that are compatible with a standard RGB computer monitor. The connectors are the HD15 type, which are standard. The signal path includes an AD8003 triple, high speed op amp. The AD8003 is configured for a gain of four. The AD8003 is provided so that an AD8175 output can be used to drive a monitor. If the board contains an AD8176, the AD8003 is not needed in the signal path. The H and V output signals are derived from the sync on common mode at the inputs, which are directly connected to the AD8175/AD8176/AD8177/AD8178 and do not require any external buffers. OUT1 is not used by the AD8177 and AD8178. Figure 16 to Figure 18 show the schematics of Output 0 to Output 2. OUT3 to OUT5 OUT3 to OUT5 are similar to OUT0 to OUT2, but do not contain an AD8003 amplifier in the signal path. If using an AD8175/AD8176/AD8177/AD8178 at the OUT3 to OUT5 outputs, a picture can be seen on the monitor, but it is dim because the gain is half of what is required. An AD8176 or AD8178 provides the proper gain for these outputs to create a true picture. OUT3 and OUT5 are not used by the AD8177 and AD8178. Figure 19 to Figure 21 show the schematics of Output 3 to Output 5. Note that, when using any of these outputs (OUT0 to OUT5), the common-mode encoding must be turned off; turning it on distorts the color in the picture. Rev. 0 | Page 4 of 33 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide OUT6 OUT6 is an RJ45 connector. It carries the differential RGB with sync on common-mode signals, typically over a CAT5 cable. If this type of signal is used as input to the AD8175/AD8177 and common-mode encoding is turned on, the proper signal appears at this output, which can then drive another CAT5 cable. This function does not work for AD8176 and AD8178 because their gains are twice that of the required signal. Figure 22 shows the schematic of Output 6. OUT7 The OUT7 output has six separate SMA connectors for each of the polarities of the RGB output signal. Similar to the SMA inputs, these outputs are useful for connecting to various test equipment. Figure 23 shows the schematic of Output 7. OUT8 OUT8 has the Gore header connector, the same as IN12 and IN13, which is compatible with various Analog Devices test equipment. Figure 24 shows the schematic of Output 8. NI USB-6501 The NI USB-6501 is a portable, digital input/output device that is used as the digital controller of the evaluation board. VBLK, CMENC, VOCM_CMENCOFF, AND VOCM_CMENCON LOGIC INPUTS The VBLK pin defines the black level of the positive output phase. The VBLK and VOCM_CMENCOFF inputs allow the user complete flexibility in defining the output CM level and the amount of overlap between the positive and negative phases, thus maximizing output headroom usage. UG-890 the AD8175-EVALZ evaluation board must be tied to GND (0 V). These jumpers are included on the board. VCOM_CMENCON and VCOM_CMENCOFF are typically set to midsupply (often ground), but can be moved by approximately ±0.5 V to accommodate cases where the desired output common-mode voltage is not midsupply (as in the case of unequal split supplies). Common-Mode Operating Modes Depending on the state of the CMENC logic input, the AD8175/AD8176/AD8177/AD8178 can be set in either of the two differential in, differential out operating modes. This only applies for CAT5 applications. See the Applications Information section in the product data sheet for more information. Common-Mode Encoding Off, CMENC Tied to Low In this mode, the CM of each RGB differential pair is removed through the device (or turned off), while the overall CM at the output is defined by the reference value, VOCM_CMENCOFF. CM noise is removed while the intended differential RGB signals are buffered and passed to the outputs. Common-Mode Encoding On, CMENC Tied to High In this mode, the CM of each RGB input is passed through the device with a gain of +1, while at the same time, the overall output CM is stripped and set equal to the voltage applied at the VOCM_CMENCON pin. The AD8175/AD8176/AD8177/ AD8178 is placed in this operation mode when used with a sync on CM scheme. Although asserted, the H and V outputs are not used in this application. CALIBRATION PATH Note that, for evaluation purposes, while running off equally split supplies (±2.5 V), the VBLK and VOCM_CMENCOFF pins on To calibrate for insertion loss due to input and output traces on the printed circuit board (PCB), a calibration through path is provided on this evaluation board. Figure 25 shows the schematic of the calibration path. Rev. 0 | Page 5 of 33 UG-890 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide QUICK START GUIDE To get started, take the following steps: For the RGB input, follow these steps: 1. 1. 3. 4. 5. 6. 7. 8. 2. 3. Connect a female-to-male VGA cable between IN0 and the video pattern generator or any video signal source. Connect a male-to-male VGA cable between OUT0 and the monitor or display. Select the IN0 to OUT0 LED in the evaluation board software, and then click APPLY. OUT0 then produces the signal from IN0 (see Figure 2). For the SMA input, follow these steps: 1. 2. 3. Connect a sine wave of 1 V p-p from the signal generator to IN12 REDN and IN12 REDP through the SMA connectors. Connect SMA connectors between OUT7 REDN and the oscilloscope and between OUT7 REDP and the oscilloscope. Select the IN12 to OUT7 LED in the evaluation board software, and then click APPLY. OUT12 produces the signal from IN12. For the CAT5 input, follow these steps: 1. 2. 3. Connect a video driver evaluation board such as the AD8134-EVALZ on IN8 through a CAT5 cable to convert the RGB output of the video pattern generator or any other video signal source to differential RGB with sync on common mode. Connect a CAT5 cable between OUT6 and a video receiver such as the AD8143-EVALZ. Select the IN8 to OUT6 LED in the evaluation board software, and then click APPLY. 13649-002 2. Remove the AD8175-EVALZ/AD8176-EVALZ/AD8177EVALZ/AD8178-EVALZ evaluation board from the box. Connect +2.5 V to VPOS, −2.5 V to VNEG, +3.3 V to VDD, and connect all ground supplies to GND. It is strongly recommended to initially operate the board from ±2.5 V to ensure basic operation. Afterwards, other power supply operation can be explored. Connect shunts between Pin 1 and Pin 2 of the following jumpers: 1, 5, 6, 10, 11, 15, 16, 20, 21, 25, 26, 30, 31, 35, 36, and 40. These shunts allow the connection of IN0 through IN7 to the AD8134. Connect shunts between Pin 2 and Pin 3 of the following jumpers: 2, 3, 4, 7, 8 9, 12, 13, 14, 17, 18, 19, 22, 23, 24, 27, 28, 29, 32, 33, 34, 37, 38, and 39. These shunts allow the operation of the ±2.5 V supply. Connect TP2 and TP3 to TP4. This connection ties the VBLK and VOCM_CMENCOFF pins to GND. Connect the NI USB-6501 board to P1 through the ribbon cable. Connect a Type B to Type A USB cable between the NI USB-6501 and a workstation running the Windows® XP operating system. Start the evaluation board software. (The procedure on the software download is included in the evaluation kit.) Figure 2. Sample of Input and Output Setting on the Evaluation Software Rev. 0 | Page 6 of 33 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide HSYNC OUT UG-890 CAT5 OUTPUT VSYNC OUT VGA OUTPUT SMA (DIFFERENTIAL) OUTPUT WORKSTATION MONITOR/DISPLAY VGA OUTPUT NI USB -6501 CAT5 INPUT CAL PATH VGA INPUT SMA (DIFFERENTIAL) INPUT OSCILLOSCOPE VGA INPUT 13649-003 SMA (DIFFERENTIAL) INPUT DC POWER SUPPLY WAVEFORM/SIGNAL GENERATOR Figure 3. Typical Evaluation Setup Rev. 0 | Page 7 of 33 3M2534-6002UB P1 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 DIO_7 DIO_6 DIO_5 DIO_4 DIO_3 DIO_2 DIO_1 DIO_0 DIO_15 J1 YEL AGND J3 J5 VNEG BLK VPOS RED VDD 0.75" Spacing 0.75" Spacing 0.75" Spacing J2 GRN GRN GRN AGND J6 AGND J4 AGND DIO_3 DIO_2 DIO_1 DIO_0 R284 10K R288 10K R283 10K R287 10K R282 10K R286 10K R290 10K AGND R281 10K AGND R285 10K AGND R289 10K FID3 FID4 FID9 FID8 FID7 FID2 FID1 FID6 FID5 D4 D3 D2 D1 D0 AB7 AB17 AGND RSTB WEB CMENC CSB SEROUT R5 VCMCM P5 VCMRCVR N5 VCMCMRCVR AB15 AB16 AB14 AB13 E15 E16 TP1 YEL R1 442 VNEG R294 1K R293 1K VPOS 1UF .01UF DIO_24 C2 C68 .01UF SKT1 UPDATEB GND1 GND2 GND3 GND4 Control Logic AD8175 VDD1 VDD2 VDD3 VDD4 E7 SERBPAR CLK SERIN E11 A3 E10 A2 E9 A1 E8 A0 AB12 AB11 AB10 AB9 AB8 E12 E14 R291 10K DIO_14 R292 10K E13 DIO_7 DIO_6 DIO_5 DIO_4 DIO_11 DIO_10 DIO_9 DIO_8 DIO_13 DIO_11 DIO_24 DIO_12 DIO_9 DIO_16 DIO_10 DIO_8 1 P1.0 GND P1.1 P2.0 P1.2 GND P1.3 P2.1 P1.4 GND P1.5 P2.2 P1.6 GND P1.7 P2.3 P0.0 GND P0.1 P2.4 P0.2 GND P0.3 P2.5 P0.4 GND P0.5 P2.6 P0.6 GND P0.7 P2.7 +5V +5V 1 1 1 1 1 1 1 USB to Digital IO Converter 1 1 C67 1 Ribbon Cable Connector for 1 1 1 Rev. 0 | Page 8 of 33 1 Figure 4. Logic Control Schematic 1 E17 E18 J7 68UF C123 BLU TP2 AGND VNEG R295 1K R296 1K VPOS R277 10K 68UF C124 AGND R276 10K PSTRNKPE4117 1UF C1 1 National Instruments USB-6501 R278 10K AGND R279 10K VNEG R298 1K R297 1K VPOS R280 10K TP3 WHT 1 VDD AGND TP4 GRN DIO_12 DIO_13 DIO_14 DIO_15 DIO_16 13649-004 1 UG-890 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide EVALUATION BOARD SCHEMATICS AND ARTWORK AB18 AB6 E6 Rev. 0 | Page 9 of 33 11 12 13 14 15 ID BIT 1 HORIZONTAL SYNC VERTICAL SYNC NC (ID BIT 3 or DATA CLOCK) 9 ID BIT 0 8 10 BLUE SHIELD 7 NC (DDC +5V) 6 SYNC RETURN 5 4 ID BIT 2 GROUND 3 BLUE RED SHIELD 2 GREEN SHIELD 1 RED GREEN P2 R0_INP_A AGND B0_INP_A G0_INP_A 2N3906 1K R299 I 2N3906 +- 2.5V Supply Jumper 2 & 3 5V Supply Jumper 1 & 2 1K R301 AGND R4 80.6 5V Supply Jumper 1 & 2 R3 80.6 +- 2.5V Supply Jumper 2 & 3 R2 80.6 5V Supply Jumper 1 & 2 +- 2.5V Supply Jumper 2 & 3 5 * (499 / 4919) = 0.507 V AD8147 Jumper 2 & 3 AGND 3 2 AGND Q2 2 AGND 3 620 R307 3 AGND R305 6.98K V 3 2 1 JMP4 AGND R303 6.98K 3 2 1 JMP3 499 R306 R304 1K VNEG VNEG R302 1K R6 37.4 R7 37.4 HSYNC VSYNC 20 BIN- 19 16 BIN+ GIN- 23 15 GIN+ RIN- RIN+ 22 3 4 V = ~0V (Transistor is Saturated) V= 4.2 mA * 1K = 4.2 (No Can Do!) I = (5 - 0.7) / 1000 = 4.3 mA SYNC HIGH TRANSISTOR IS ON V = 2.5 * (1000 / 7980) - 2.5 = -2.19 SYNC LOW TRANSISTOR IS OFF AGND AGND AGND 37.4 R5 2.5 * (1119 / 5539) AGND = 0.505 V R300 4.42K VNEG x2 + + AD8134ACPZ U1 VPOS VS1+ JMP2 VNEG C3 0.1UF C89 10000PF - C4 0.1UF C90 10000PF + - + - + VS12 1 11 VS2+ VS25 JMP1 17 VS3+ VS314 AD8134 Jumper 1 & 2 1 Figure 5. Input 0 2 1 Q1 3 18 SYNCLVL 8 24 VS4+ VS421 VPOS 6 9 10 12 13 1 ROUT- GOUT+ GOUT- BOUT+ BOUTOPD AGND PAD PAD 7 ROUT+ AGND AGND B0_INN_B B0_INP_B G0_INN_B G0_INP_B R0_INN_B R0_INP_B 3 2 1 JMP5 AGND VNEG 49.9 R118 49.9 R116 49.9 R114 AD8147 Jumper 2 & 3 AD8134 Jumper 1 & 2 49.9 R119 49.9 R117 49.9 R115 B0_INN_C B0_INP_C G0_INN_C G0_INP_C R0_INN_C R0_INP_C R122 R121 R120 100 100 100 B B G G R R SKT1 PBGA-676_27X27 CHANNEL=0 AF17 AE17 AD17 AD16 AE16 AF16 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide UG-890 13649-005 2 1 Rev. 0 | Page 10 of 33 12 13 14 15 ID BIT 1 VERTICAL SYNC NC (ID BIT 3 or DATA CLOCK) 11 HORIZONTAL SYNC 9 10 8 BLUE SHIELD ID BIT 0 7 NC (DDC +5V) 6 SYNC RETURN 5 4 ID BIT 2 GROUND 3 BLUE RED SHIELD 2 GREEN GREEN SHIELD 1 RED P3 AGND B1_INP_A G1_INP_A R1_INP_A R10 80.6 1K R321 I +- 2.5V Supply Jumper 2 & 3 2N3906 AGND R12 80.6 2N3906 AGND AGND 2 5V Supply Jumper 1 & 2 1K R320 +- 2.5V Supply Jumper 2 & 3 5V Supply Jumper 1 & 2 R11 80.6 5V Supply Jumper 1 & 2 +- 2.5V Supply Jumper 2 & 3 5 * (499 / 4919) = 0.507 V 3 2 Q4 2 AGND 3 AD8147 Jumper 2 & 3 1 1 JMP7 JMP6 620 R319 AGND R314 6.98K V 3 2 1 JMP9 AGND R315 6.98K 3 2 1 JMP8 499 R318 VNEG 3 AD8134 Jumper 1 & 2 Q3 1 Figure 6. Input 1 3 VNEG VNEG R313 1K R316 1K 37.4 R8 37.4 R9 20 VSYNC 19 HSYNC 16 BIN- 15 BIN+ 23 GIN- 22 GIN+ 3 RIN- 4 RIN+ V = ~0V (Transistor is Saturated) V= 4.2 mA * 1K = 4.2 (No Can Do!) I = (5 - 0.7) / 1000 = 4.3 mA SYNC HIGH TRANSISTOR IS ON V = 2.5 * (1000 / 7980) - 2.5 = -2.19 SYNC LOW TRANSISTOR IS OFF AGND AGND AGND 37.4 R13 2.5 * (1119 / 5539) AGND = 0.505 V R317 4.42K VNEG x2 + + AD8134ACPZ U2 VPOS C11 0.1UF C97 10000PF - + - + - + 0.1UF C98 10000PF C12 VS12 17 VS25 24 VS3+ VS314 18 SYNCLVL 8 VS1+ 11 VS2+ VS4+ VS421 VPOS G1_INP_B G1_INN_B B1_INP_B B1_INN_B GOUT+ 9 GOUT- 10 BOUT+ 12 BOUT- 13 AGND R1_INN_B ROUT- 6 AGND PAD PAD OPD 1 R1_INP_B ROUT+ 7 AGND 3 2 1 JMP10 AGND VNEG 49.9 R126 49.9 R128 49.9 R130 AD8147 Jumper 2 & 3 AD8134 Jumper 1 & 2 49.9 R125 49.9 R127 49.9 R129 B1_INN_C B1_INP_C G1_INN_C G1_INP_C R1_INN_C R1_INP_C R123 R124 R131 100 100 100 R B B G G R SKT1 PBGA-676_27X27 CHANNEL=1 AF14 AE14 AD14 AD13 AE13 AF13 13649-006 2 1 UG-890 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide Rev. 0 | Page 11 of 33 9 10 11 12 13 14 15 ID BIT 1 HORIZONTAL SYNC VERTICAL SYNC NC (ID BIT 3 or DATA CLOCK) 8 BLUE SHIELD ID BIT 0 7 GREEN SHIELD NC (DDC +5V) 6 SYNC RETURN 5 4 GROUND 3 BLUE ID BIT 2 RED SHIELD 2 P4 1 RED GREEN R2_INP_A AGND B2_INP_A G2_INP_A R16 80.6 1K R335 I +- 2.5V Supply Jumper 2 & 3 AGND 2N3906 R18 80.6 2N3906 AGND 2 5V Supply Jumper 1 & 2 1K R334 +- 2.5V Supply Jumper 2 & 3 5V Supply Jumper 1 & 2 R17 80.6 5V Supply Jumper 1 & 2 +- 2.5V Supply Jumper 2 & 3 AGND Q6 2 AGND 3 5 * (499 / 4919) = 0.507 V 3 2 JMP12 620 R333 AGND R328 6.98K V 3 2 1 JMP14 AGND R329 6.98K 3 2 1 JMP13 499 R332 VNEG 3 1 VNEG R327 1K VNEG R330 1K R15 37.4 R14 37.4 HSYNC VSYNC 20 BIN- 19 16 BIN+ GIN- 23 15 GIN+ RIN- RIN+ 22 3 4 V = ~0V (Transistor is Saturated) V= 4.2 mA * 1K = 4.2 (No Can Do!) I = (5 - 0.7) / 1000 = 4.3 mA SYNC HIGH TRANSISTOR IS ON V = 2.5 * (1000 / 7980) - 2.5 = -2.19 SYNC LOW TRANSISTOR IS OFF AGND AGND AGND 37.4 R19 2.5 * (1119 / 5539) AGND = 0.505 V R331 4.42K VNEG x2 + + AD8134ACPZ U3 VPOS VS1+ JMP11 C16 0.1UF C102 10000PF - + - + - + 0.1UF C103 10000PF C17 VS12 AD8147 Jumper 2 & 3 1 VS25 AD8134 Jumper 1 & 2 Q5 1 Figure 7. Input 2 3 8 17 VS3+ VS314 VS2+ 18 SYNCLVL 11 24 VS4+ VS421 VPOS 6 9 10 12 13 1 ROUT- GOUT+ GOUT- BOUT+ BOUTOPD AGND PAD PAD 7 ROUT+ AGND AGND B2_INN_B B2_INP_B G2_INN_B G2_INP_B R2_INN_B R2_INP_B 3 2 1 JMP15 AGND VNEG 49.9 R135 49.9 R137 49.9 R139 AD8147 Jumper 2 & 3 AD8134 Jumper 1 & 2 49.9 R134 49.9 R136 49.9 R138 B2_INN_C B2_INP_C G2_INN_C G2_INP_C R2_INN_C R2_INP_C R132 R133 R140 100 100 100 AF11 AE11 AD11 AD10 AE10 AF10 SKT1 PBGA-676_27X27 CHANNEL=2 B B G G R R AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide UG-890 13649-007 2 1 Rev. 0 | Page 12 of 33 5 6 7 8 9 10 11 12 13 14 15 GROUND BLUE SHIELD NC (DDC +5V) SYNC RETURN ID BIT 0 ID BIT 1 HORIZONTAL SYNC VERTICAL SYNC NC (ID BIT 3 or DATA CLOCK) 4 RED SHIELD 3 BLUE ID BIT 2 GREEN SHIELD 2 GREEN P5 1 RED AGND B3_INP_A G3_INP_A R3_INP_A R22 80.6 1K R349 I +- 2.5V Supply Jumper 2 & 3 5V Supply Jumper 1 & 2 1K R348 +- 2.5V Supply Jumper 2 & 3 5V Supply Jumper 1 & 2 R23 80.6 5V Supply Jumper 1 & 2 +- 2.5V Supply Jumper 2 & 3 5 * (499 / 4919) = 0.507 V AGND 2N3906 R24 80.6 2N3906 AGND 3 2 AGND 3 AD8147 Jumper 2 & 3 Q8 2 AGND JMP17 620 R347 AGND R342 6.98K V 3 2 1 JMP19 AGND R343 6.98K 3 2 1 JMP18 499 R346 VNEG 3 1 VNEG VNEG R341 1K R344 1K 37.4 R20 37.4 R21 HSYNC VSYNC 20 BIN- BIN+ GIN- GIN+ RIN- RIN+ 19 16 15 23 22 3 4 V = ~0V (Transistor is Saturated) V= 4.2 mA * 1K = 4.2 (No Can Do!) I = (5 - 0.7) / 1000 = 4.3 mA SYNC HIGH TRANSISTOR IS ON V = 2.5 * (1000 / 7980) - 2.5 = -2.19 SYNC LOW TRANSISTOR IS OFF AGND AGND AGND 37.4 R25 2.5 * (1119 / 5539) AGND = 0.505 V R345 4.42K VNEG x2 + + AD8134ACPZ U4 VPOS C21 0.1UF C107 10000PF - C22 0.1UF C108 10000PF + - + - + VS12 JMP16 11 VS2+ VS25 AD8134 Jumper 1 & 2 1 Figure 8. Input 3 2 1 Q7 3 17 VS3+ VS314 VS1+ 18 SYNCLVL 8 24 VS4+ VS421 VPOS AGND PAD PAD OPD 1 BOUT- 13 BOUT+ 12 GOUT- 10 GOUT+ 9 ROUT- 6 ROUT+ 7 AGND AGND B3_INN_B B3_INP_B G3_INN_B G3_INP_B R3_INN_B R3_INP_B 3 2 1 JMP20 AGND VNEG 49.9 R144 49.9 R146 49.9 R148 AD8147 Jumper 2 & 3 AD8134 Jumper 1 & 2 49.9 R143 49.9 R145 49.9 R147 B3_INN_C B3_INP_C G3_INN_C G3_INP_C R3_INN_C R3_INP_C R141 R142 R149 100 100 100 AF8 AE8 AD8 AD7 AE7 AF7 SKT1 PBGA-676_27X27 CHANNEL=3 B B G G R R 13649-008 2 1 UG-890 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide 5 6 7 8 9 10 11 12 13 14 15 BLUE SHIELD NC (DDC +5V) SYNC RETURN ID BIT 0 ID BIT 1 HORIZONTAL SYNC VERTICAL SYNC NC (ID BIT 3 or DATA CLOCK) 4 ID BIT 2 GROUND 3 BLUE RED SHIELD 2 GREEN SHIELD 1 RED GREEN P6 AGND B4_INP_A G4_INP_A R4_INP_A R27 80.6 AGND R28 80.6 2N3906 1K R363 5V Supply Jumper 1 & 2 I 2N3906 AGND AGND +- 2.5V Supply Jumper 2 & 3 1K R362 +- 2.5V Supply Jumper 2 & 3 5V Supply Jumper 1 & 2 R26 80.6 5V Supply Jumper 1 & 2 +- 2.5V Supply Jumper 2 & 3 5 * (499 / 4919) = 0.507 V 3 AGND 620 3 AGND R356 6.98K V 3 2 1 JMP24 AGND R357 6.98K 3 2 1 R358 1K VNEG R355 1K RIN- 3 20 VSYNC 19 HSYNC 16 BIN- 15 BIN+ 23 GIN- 22 GIN+ RIN+ 4 SYNCLVL 18 V = ~0V (Transistor is Saturated) V= 4.2 mA * 1K = 4.2 (No Can Do!) I = (5 - 0.7) / 1000 = 4.3 mA SYNC HIGH TRANSISTOR IS ON V = 2.5 * (1000 / 7980) - 2.5 = -2.19 SYNC LOW TRANSISTOR IS OFF B4_INN_A G4_INN_A R4_INN_A 2.5 * (1119 / 5539) AGND = 0.505 V R359 4.42K VNEG R361 JMP23 499 R360 JMP22 VNEG x2 + + AD8134ACPZ U5 VPOS C23 0.1UF C109 10000PF - C24 0.1UF C110 10000PF + - + - + 2 VNEG VS1- 17 VS25 24 VS3+ VS314 AD8147 Jumper 2 & 3 1 1 3 3 8 VS1+ 11 VS2+ VS4+ VS421 2 AGND PAD PAD OPD 1 BOUT- 13 BOUT+ 12 GOUT- 10 GOUT+ 9 ROUT- 6 ROUT+ 7 AGND AGND AGND 49.9 R153 49.9 R155 49.9 R157 0.1UF C129 3 2 1 JMP25 AGND VNEG B4_INN_B B4_INP_B G4_INN_B G4_INP_B R4_INN_B R4_INP_B B4_FB G4_FB AGND A1 1 VO V+ V3 R4_FB 2 VPOS B4_INN_C B4_INP_C G4_INN_C G4_INP_C R4_INN_C R4_INP_C 499 R436 499 R308 499 R312 1.2V Bandgap ADR280ART AD8147 Jumper 2 & 3 AD8134 Jumper 1 & 2 49.9 R152 49.9 R154 49.9 R156 C7 IN2- IN2+ IN1- 9 IN3- - + - + - + ADA4861 IN1+ 10 IN3+ 13 12 6 5 U9 0.1UF C93 10000PF AGND R150 R151 R158 100 100 100 VPOS OUT3 VNEG C6 7 C5 B4_FB 0.1UF C91 10000PF 8 G4_FB R4_FB 0.1UF C92 B B G G R R SKT1 AGND AGND AGND AGND 53.6 R311 130 R31 53.6 R310 130 R30 53.6 R309 130 R29 1.2 * 53.6 / 183.6 = 0.350 V AGND PBGA-676_27X27 CHANNEL=4 AF5 AE5 AD5 AD4 AE4 AF4 10000PF OUT2 14 OUT1 PD3 1 PD2 JMP21 PD1 3 AD8134 Jumper 1 & 2 +VS 4 2 Rev. 0 | Page 13 of 33 2 1 Figure 9. Input 4 Q10 -VS 2 11 Q9 B4_INN_A G4_INN_A R4_INN_A 13649-009 VPOS AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide UG-890 2 1 12 13 14 15 ID BIT 1 VERTICAL SYNC NC (ID BIT 3 or DATA CLOCK) 11 HORIZONTAL SYNC 9 10 8 BLUE SHIELD ID BIT 0 7 NC (DDC +5V) 6 SYNC RETURN 5 GROUND 4 ID BIT 2 RED SHIELD 3 BLUE GREEN SHIELD 2 P7 1 RED GREEN AGND B5_INP_A G5_INP_A R5_INP_A R36 80.6 AGND R37 80.6 2N3906 1K R372 I 2N3906 +- 2.5V Supply Jumper 2 & 3 5V Supply Jumper 1 & 2 1K R371 +- 2.5V Supply Jumper 2 & 3 5V Supply Jumper 1 & 2 R35 80.6 5V Supply Jumper 1 & 2 +- 2.5V Supply Jumper 2 & 3 5 * (499 / 4919) = 0.507 V AGND 3 2 AGND AGND 3 2 1 AGND R365 6.98K V 3 2 1 JMP29 AGND VNEG R364 1K RIN+ RIN- GIN+ GIN- BIN+ BIN- HSYNC VSYNC 4 3 22 23 15 16 19 20 V = ~0V (Transistor is Saturated) V= 4.2 mA * 1K = 4.2 (No Can Do!) I = (5 - 0.7) / 1000 = 4.3 mA SYNC HIGH TRANSISTOR IS ON V = 2.5 * (1000 / 7980) - 2.5 = -2.19 SYNC LOW TRANSISTOR IS OFF B5_INN_A G5_INN_A R5_INN_A 2.5 * (1119 / 5539) AGND = 0.505 V R367 1K VNEG 620VPOS R370 JMP28 499 R366 6.98K 3 JMP27 U6 VPOS C25 0.1UF C111 10000PF VNEG x2 + + AD8134ACPZ - + - + - + 0.1UF C112 10000PF C26 18 SYNCLVL R368 4.42K 8 VS1+ VS12 R369 11 VS2+ VS25 VNEG 17 VS3+ VS314 AD8147 Jumper 2 & 3 1 1 3 3 24 VS4+ VS421 1 6 9 10 12 13 1 ROUT- GOUT+ GOUT- BOUT+ BOUTOPD AGND PAD PAD 7 ROUT+ AGND AGND AGND 0.1UF 49.9 3 2 1 AD8147 Jumper 2 & 3 AD8134 Jumper 1 & 2 49.9 R161 49.9 R163 49.9 R165 B5_FB G5_FB AGND A2 1 VO V+ V3 R5_FB 2 VPOS 499 R437 499 R322 499 R326 1.2V Bandgap ADR280ART R162 49.9 R164 49.9 R166 JMP30 AGND VNEG C130 B5_INN_B B5_INP_B G5_INN_B G5_INP_B R5_INN_B R5_INP_B 9 10 13 12 6 5 IN3- IN3+ IN2- IN2+ IN1- IN1+ - + - + - + ADA4861 U10 0.1UF C94 10000PF C8 B5_INN_C B5_INP_C G5_INN_C G5_INP_C R5_INN_C R5_INP_C AGND PD3 JMP26 PD2 3 100 100 100 VPOS R159 R160 R167 4 AD8134 Jumper 1 & 2 PD1 2 2 1 Rev. 0 | Page 14 of 33 C95 8 OUT3 C10 B5_FB G5_FB 0.1UF C96 10000PF 14 OUT2 R5_FB 0.1UF 7 VNEG C9 10000PF OUT1 +VS Figure 10. Input 5 Q12 -VS 2 11 Q11 AB1 B B G G R R SKT1 PBGA-676_27X27 CHANNEL=5 AGND AGND AGND AGND 53.6 R325 130 R32 53.6 R324 130 R33 53.6 R323 130 R34 1.2 * 53.6 / 183.6 = 0.350 V AGND AC1 AC2 AC3 AB3 AB2 B5_INN_A G5_INN_A R5_INN_A 13649-010 UG-890 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide 2 1 4 12 ID BIT 1 14 15 VERTICAL SYNC NC (ID BIT 3 or DATA CLOCK) 13 11 ID BIT 0 HORIZONTAL SYNC 9 10 NC (DDC +5V) SYNC RETURN 8 7 BLUE SHIELD 6 RED SHIELD GREEN SHIELD 5 3 BLUE ID BIT 2 GROUND 2 P8 1 RED GREEN AGND B6_INP_A G6_INP_A R6_INP_A R41 80.6 1K R381 I +- 2.5V Supply Jumper 2 & 3 5V Supply Jumper 1 & 2 1K R380 2N3906 AGND R43 80.6 +- 2.5V Supply Jumper 2 & 3 5V Supply Jumper 1 & 2 R42 80.6 5V Supply Jumper 1 & 2 +- 2.5V Supply Jumper 2 & 3 5 * (499 / 4919) = 0.507 V 2N3906 AGND 3 2 AGND AGND JMP32 620 3 AGND R374 6.98K V 3 2 1 JMP34 AGND R375 6.98K 3 2 1 VNEG R373 1K R376 1K RIN+ RIN- GIN+ GIN- BIN+ BIN- HSYNC VSYNC 4 3 22 23 15 16 19 20 SYNCLVL 18 V = ~0V (Transistor is Saturated) V= 4.2 mA * 1K = 4.2 (No Can Do!) I = (5 - 0.7) / 1000 = 4.3 mA SYNC HIGH TRANSISTOR IS ON V = 2.5 * (1000 / 7980) - 2.5 = -2.19 SYNC LOW TRANSISTOR IS OFF B6_INN_A G6_INN_A R6_INN_A 2.5 * (1119 / 5539) AGND = 0.505 V R377 4.42K VNEG R379 JMP33 499 R378 VNEG VNEG x2 + + AD8134ACPZ U7 VPOS + - C113 0.1UF C28 0.1UF C114 10000PF + - + - C27 10000PF 17 AD8147 Jumper 2 & 3 1 1 24 VS3+ 1 3 3 8 VS1+ 11 VS2+ 2 VS15 VS2- VS4+ 14 VS321 VS4- JMP31 B6_INP_B B6_INN_B BOUT+ 12 BOUT- 13 AGND PAD PAD AGND G6_INN_B GOUT- 10 0.1UF C131 G6_INP_B GOUT+ 9 AGND R6_INN_B ROUT- 6 OPD 1 R6_INP_B ROUT+ 7 AGND B6_FB G6_FB AGND A3 1 V+ VO V3 R6_FB 2 499 R438 499 R336 499 R340 VPOS AD8147 Jumper 2 & 3 AD8134 Jumper 1 & 2 49.9 R170 49.9 R172 49.9 R174 1.2V Bandgap ADR280ART 3 2 1 JMP35 AGND VNEG 49.9 R171 49.9 R173 49.9 R175 9 10 13 12 6 5 IN3- IN3+ IN2- IN2+ IN1- IN1+ - + - + - + ADA4861 U11 0.1UF C99 10000PF C13 B6_INN_C B6_INP_C G6_INN_C G6_INP_C R6_INN_C R6_INP_C 3 PD3 2 2 PD2 AGND VPOS R168 R169 R176 4 AD8134 Jumper 1 & 2 1 PD1 Rev. 0 | Page 15 of 33 OUT3 8 VNEG 0.1UF C101 10000PF C15 B6_FB G6_FB R6_FB 0.1UF C100 10000PF C14 100 100 100 OUT2 14 OUT1 7 +VS Figure 11. Input 6 Q14 -VS 2 11 Q13 AGND AGND AGND AGND B B G G R R SKT1 PBGA-676_27X27 CHANNEL=6 53.6 R339 130 R38 53.6 R338 130 R39 53.6 R337 130 R40 1.2 * 53.6 / 183.6 = 0.350 V AGND W1 W2 W3 V3 V2 V1 B6_INN_A G6_INN_A R6_INN_A 13649-011 VPOS AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide UG-890 2 1 5 6 7 8 9 10 11 12 13 14 15 BLUE SHIELD NC (DDC +5V) SYNC RETURN ID BIT 0 ID BIT 1 HORIZONTAL SYNC VERTICAL SYNC NC (ID BIT 3 or DATA CLOCK) 4 ID BIT 2 GROUND 3 BLUE RED SHIELD 2 GREEN SHIELD 1 RED GREEN P9 R7_INP_A AGND B7_INP_A G7_INP_A R47 80.6 1K R390 I 5V Supply Jumper 1 & 2 +- 2.5V Supply Jumper 2 & 3 1K R389 AGND 2N3906 R49 80.6 5V Supply Jumper 1 & 2 +- 2.5V Supply Jumper 2 & 3 R48 80.6 5V Supply Jumper 1 & 2 +- 2.5V Supply Jumper 2 & 3 5 * (499 / 4919) = 0.507 V 2N3906 AGND AGND 3 2 AGND 620 3 AGND R383 6.98K V 3 2 1 JMP39 AGND R384 6.98K 3 2 1 R385 1K R382 1K BIN- HSYNC VSYNC 16 19 20 BIN+ GIN- 15 GIN+ 23 RIN- RIN+ 22 3 4 V = ~0V (Transistor is Saturated) V= 4.2 mA * 1K = 4.2 (No Can Do!) I = (5 - 0.7) / 1000 = 4.3 mA SYNC HIGH TRANSISTOR IS ON V = 2.5 * (1000 / 7980) - 2.5 = -2.19 SYNC LOW TRANSISTOR IS OFF B7_INN_A G7_INN_A R7_INN_A 2.5 * (1119 / 5539) AGND = 0.505 V VNEG VNEG R388 JMP38 499 R386 4.42K 18 SYNCLVL R387 VNEG x2 + + AD8134ACPZ U8 VPOS VS12 AD8147 Jumper 2 & 3 1 1 JMP37 C29 0.1UF C115 10000PF VS2- AD8134 Jumper 1 & 2 3 3 17 VS3+ VS3- 5 - C30 0.1UF C116 10000PF + - + - + VS2+ 8 VS1+ 11 24 VS4+ VS4- 14 21 VNEG AGND AGND 0.1UF 49.9 R180 49.9 R182 49.9 R184 3 2 1 B7_FB G7_FB AGND 499 R439 499 R350 499 R354 ADR280ART A4 1 VO V+ V3 R7_FB 2 VPOS AD8147 Jumper 2 & 3 AD8134 Jumper 1 & 2 49.9 R179 49.9 R181 49.9 R183 1.2V Bandgap JMP40 AGND VNEG C132 B7_INN_B BOUT- 13 AGND B7_INP_B BOUT+ 12 PAD G7_INN_B GOUT- 10 PAD G7_INP_B GOUT+ 9 1 R7_INN_B ROUT- 6 OPD R7_INP_B ROUT+ 7 AGND 9 10 13 12 6 5 IN3- IN3+ IN2- IN2+ IN1- IN1+ - + - + - + ADA4861 U12 0.1UF C104 10000PF C18 B7_INN_C B7_INP_C G7_INN_C G7_INP_C R7_INN_C R7_INP_C AGND VPOS R177 R178 R185 14 8 OUT2 OUT3 VNEG C20 B7_FB G7_FB R7_FB 0.1UF C106 10000PF 7 0.1UF C105 10000PF C19 100 100 100 OUT1 PD3 1 PD2 JMP36 PD1 3 VPOS 4 2 2 1 Rev. 0 | Page 16 of 33 +VS Figure 12. Input 7 Q16 -VS 2 11 Q15 AGND AGND AGND AGND B B G G R R SKT1 PBGA-676_27X27 CHANNEL=7 53.6 R353 130 R44 53.6 R352 130 R45 53.6 R351 130 R46 1.2 * 53.6 / 183.6 = 0.350 V AGND T1 T2 T3 R3 R2 R1 B7_INN_A G7_INN_A R7_INN_A 13649-012 UG-890 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide 2 1 GND PINS GND PINS Figure 13. Input 8 to Input 11 Rev. 0 | Page 17 of 33 10 9 8 7 6 5 4 3 2 1 P12 10 9 8 7 6 5 4 3 2 1 P10 AGND AGND B10_INN B10_INP G10_INN G10_INP R10_INN R10_INP B8_INN B8_INP G8_INN G8_INP R8_INN R8_INP R194 100 R193 100 R192 100 R187 100 R186 100 R188 100 B B G G R R SKT1 B B G G R R SKT1 PBGA-676_27X27 CHANNEL=10 A10 B10 C10 C11 B11 A11 PBGA-676_27X27 CHANNEL=8 A16 B16 C16 C17 B17 A17 GND PINS GND PINS 10 9 8 7 6 5 4 3 2 1 P13 10 9 8 7 6 5 4 3 2 1 P11 AGND AGND B11_INN B11_INP G11_INN G11_INP R11_INN R11_INP B9_INN B9_INP G9_INN G9_INP R9_INN R9_INP R195 100 R196 100 R197 100 R191 100 R190 100 R189 100 B B G G R R SKT1 B B G G R R SKT1 PBGA-676_27X27 CHANNEL = 11 A7 B7 C7 C8 B8 A8 PBGA-676_27X27 CHANNEL = 9 A13 B13 C13 C14 B14 A14 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide UG-890 13649-013 Rev. 0 | Page 18 of 33 AGND J13 J12 J11 J10 J9 J8 ROS32K243-40ME3 ROS32K243-40ME3 ROS32K243-40ME3 ROS32K243-40ME3 ROS32K243-40ME3 ROS32K243-40ME3 AGND A4 SKT1 R B B G G R PBGA-676_27X27 CHANNEL=12 B4 B12_INN C4 B12_INP C5 G12_INN B5 G12_INP A5 R204 49.9 R202 49.9 R12_INN R203 49.9 R205 49.9 R12_INP R206 49.9 R208 49.9 AGND AGND J19 J18 J17 J16 J15 J14 ROS32K243-40ME3 ROS32K243-40ME3 ROS32K243-40ME3 ROS32K243-40ME3 ROS32K243-40ME3 ROS32K243-40ME3 B13_INN B13_INP G13_INN G13_INP R13_INN R13_INP R199 49.9 R200 49.9 R207 49.9 R198 49.9 R201 49.9 R209 49.9 AGND AGND B B G G R R SKT1 PBGA-676_27X27 CHANNEL=13 E1 E2 E3 D3 D2 D1 13649-014 UG-890 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide Figure 14. Input 12 to Input 13 1 * PIN SWAP Rev. 0 | Page 19 of 33 GND PINS 7 * PIN SWAP AGND B B SKT1 17 17 19 20 21 22 23 24 25 19 20 21 22 23 24 25 18 16 18 15 16 14 13 15 14 12 10 9 7 8 6 5 4 3 1 2 P15 13 * * * * 12 GND PINS PIN SWAP PIN SWAP PIN SWAP PIN SWAP 11 AGND R215 49.9 J1 B14_INN G G R R PBGA-676_27X27 CHANNEL=14 J2 J3 B14_INP G14_INN H3 H2 G14_INP H1 R14_INN R214 49.9 AGND R14_INP R213 49.9 R210 49.9 11 10 9 8 * PIN SWAP 6 5 4 3 2 P14 * PIN SWAP R211 49.9 AGND M1 B15_INN SKT1 B B G G R R PBGA-676_27X27 CHANNEL=15 M2 M3 L3 B15_INP G15_INN G15_INP L2 AGND AGND L1 R221 49.9 R216 49.9 R15_INN R219 49.9 R218 49.9 R15_INP R220 49.9 R217 49.9 13649-015 R212 49.9 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide Figure 15. Input 14 to Input 15 UG-890 V H B0_OUTN_A H0_OUT_A V0_OUT_A AC19 AC20 B0_OUTP_A AE20 AF20 G0_OUTN_A G0_OUTP_A AD19 AD20 R0_OUTN_A R0_OUTP_A AE19 AF19 SKT1 PBGA-676_27X27 CHANNEL= 0 B B G G R R 0 R60 75 R225 75 R224 75 R222 0 R59 75 R223 75 R227 75 R226 AGND R61 499 AGND R62 499 V0_OUT_B H0_OUT_B B0_OUTN_B B0_OUTP_B G0_OUTN_B G0_OUTP_B R0_OUTN_B R0_OUTP_B R52 75 Figure 16. Output 0 and 1/2 of VCM Circuit Rev. 0 | Page 20 of 33 R50 75 AGND R403 150 AGND 1/2 of VCMCM (See Page 2) VNEG R404 300 R405 300 VPOS R51 75 VCMR0 VCMB0 VCMG0 VCMR0 VNEG R401 300 R402 300 VPOS 24.9 R394 24.9 R395 24.9 R396 R400 150 VNEG AGND 300 R393 300 R392 300 R391 VCMG0 17 FB3 16 IN3- 15 IN3+ 20 FB2 21 IN2- 22 IN2+ 2 FB1 3 IN1- 4 IN1+ - + - + - + U13 AD8003ACPZ 0.1UF C118 AGND VNEG R398 300 R397 300 VPOS 10000PF C32 VS16 AGND 24 R53 75 VS2- R54 75 VS313 R55 75 C117 0.1UF NC1 7 VS1+ 1 C31 PD1 5 NC2 9 VPOS VS2+ 19 VS3+ 18 10000PF PD2 23 PD3 14 NC3 11 AGND R399 150 PAD PAD OUT3 12 OUT2 10 OUT1 8 AGND VCMB0 AGND B0_OUTP_C G0_OUTP_C R0_OUTP_C 75 R58 75 R57 75 R56 B0_OUTP_D G0_OUTP_D R0_OUTP_D AGND 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 P16 VERTICAL SYNC HORIZONTAL SYNC ID BIT 1 ID BIT 0 SYNC RETURN NC (DDC +5V) BLUE SHIELD GREEN SHIELD RED SHIELD GROUND ID BIT 2 BLUE GREEN RED UG-890 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide 13649-016 G1_OUTP_A G1_OUTN_A B1_OUTP_A B1_OUTN_A AD22 AD23 AE23 AF23 V1_OUT_A H1_OUT_A R1_OUTN_A AE22 H AC22 V AC23 R1_OUTP_A AF22 PBGA-676_27X27 CHANNEL=1 B B G G R R SKT1 0 R73 75 R231 75 R230 75 R228 0 R72 75 R229 75 R233 75 R232 AGND R74 499 AGND R75 499 V1_OUT_B H1_OUT_B B1_OUTN_B B1_OUTP_B G1_OUTN_B G1_OUTP_B R1_OUTN_B R1_OUTP_B R65 75 R68 75 Figure 17. Output 1 and 2/2 of VCM Circuit Rev. 0 | Page 21 of 33 R63 75 R66 75 VNEG AGND R418 150 AGND AGND VCMR1 1/2 of VCMCM (See Page 2) R419 300 R420 300 VPOS R64 75 R67 75 VCMB1 VCMG1 VCMR1 VNEG R416 300 R417 300 VPOS 24.9 R409 24.9 R410 24.9 R411 VNEG AGND R415 150 300 R408 300 R407 300 R406 VCMG1 17 FB3 16 IN3- 15 IN3+ 20 FB2 21 IN2- 22 IN2+ 2 FB1 3 IN1- 4 IN1+ - + - + - + 0.1UF U14 AD8003ACPZ AGND VNEG R413 300 R412 300 VPOS 0.1UF C120 10000PF C34 24 VS213 VS3- VPOS PD2 23 PD3 14 9 NC2 11 NC3 VS1+ 1 C33 PD1 5 NC1 7 VS16 VS2+ 19 VS3+ 18 C119 AGND R414 150 PAD PAD OUT3 12 OUT2 10 OUT1 8 AGND VCMB1 AGND B1_OUTP_C G1_OUTP_C R1_OUTP_C 75 R71 75 R70 75 R69 B1_OUTP_D G1_OUTP_D R1_OUTP_D AGND 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 P17 VERTICAL SYNC HORIZONTAL SYNC ID BIT 1 ID BIT 0 SYNC RETURN NC (DDC +5V) BLUE SHIELD GREEN SHIELD RED SHIELD GROUND ID BIT 2 BLUE GREEN RED 13649-017 10000PF AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide UG-890 V H B2_OUTN_A H2_OUT_A V2_OUT_A Y23 W23 B2_OUTP_A W25 W26 G2_OUTN_A W24 G2_OUTP_A Y24 PBGA-676_27X27 CHANNEL=2 B B G G R2_OUTN_A R2_OUTP_A Y25 Y26 0 R86 75 R237 75 R236 75 R234 0 R85 75 R235 75 R239 75 R238 R88 499 AGND R87 499 AGND R2_OUTP_B V2_OUT_B H2_OUT_B B2_OUTN_B B2_OUTP_B G2_OUTN_B G2_OUTP_B R2_OUTN_B R78 75 Figure 18. Output 2 Rev. 0 | Page 22 of 33 R76 75 VNEG AGND R433 150 AGND VCMR2 1/2 of VCMCM (See Page 2) R434 300 R435 VPOS R77 75 VCMB2 VCMG2 VCMR2 VNEG R431 300 R432 300 VPOS 24.9 R424 24.9 R425 24.9 R426 VNEG AGND R430 150 300 R423 300 R422 300 R421 FB1 IN1- IN1+ VCMG2 17 FB3 16 IN3- 15 IN3+ 20 FB2 21 IN2- 22 IN2+ 2 3 4 - + - + - + AD8003ACPZ U15 AGND VNEG R428 300 R427 300 VPOS 0.1UF C122 10000PF C36 VS16 R R 24 AGND VS2- R79 75 VS313 R80 75 NC1 7 R81 75 C121 0.1UF PD1 5 NC2 9 SKT1 VS2+ 19 VS3+ 18 NC3 11 VPOS VS1+ 1 C35 PD2 23 PD3 14 10000PF AGND R429 150 VCMB2 B2_OUTP_C OUT3 12 AGND G2_OUTP_C OUT2 10 PAD PAD R2_OUTP_C OUT1 8 AGND 75 R84 75 R83 75 R82 B2_OUTP_D G2_OUTP_D R2_OUTP_D AGND GROUND RED SHIELD 6 SYNC RETURN ID BIT 0 ID BIT 1 10 11 12 15 14 VERTICAL SYNC HORIZONTAL SYNC NC (DDC +5V) 9 13 BLUE SHIELD 8 GREEN SHIELD ID BIT 2 5 7 BLUE 4 GREEN RED 3 2 1 P18 13649-018 UG-890 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide V T23 H U23 T26 T25 T24 U24 U25 U26 PBGA-676_27X27 CHANNEL=3 B B G G R SKT1 V3_OUT_A H3_OUT_A B3_OUTN_A B3_OUTP_A G3_OUTN_A G3_OUTP_A R3_OUTN_A R3_OUTP_A 0 R93 75 R245 75 R243 75 R241 0 R92 75 R244 75 R242 75 R240 R95 499 AGND R94 499 AGND V3_OUT_B H3_OUT_B B3_OUTN_B B3_OUTP_B G3_OUTN_B G3_OUTP_B R3_OUTN_B R3_OUTP_B R91 75 R89 75 R90 75 AGND AGND ID BIT 1 HORIZONTAL SYNC VERTICAL SYNC NC (ID BIT 3 or DATA CLOCK) 13 14 15 ID BIT 0 SYNC RETURN NC (DDC +5V) BLUE SHIELD GREEN SHIELD RED SHIELD GROUND ID BIT 2 BLUE GREEN RED 12 11 10 9 8 7 6 5 4 3 2 1 P19 13649-019 R AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide Figure 19. Output 3 Rev. 0 | Page 23 of 33 UG-890 V H SKT1 B4_OUTP_A B4_OUTN_A H4_OUT_A V4_OUT_A N25 N26 P23 N23 G4_OUTP_A P24 G4_OUTN_A R4_OUTN_A P25 N24 R4_OUTP_A P26 PBGA-676_27X27 CHANNEL=4 B B G G R R 0 R100 75 R251 75 R249 75 R247 0 R99 75 R250 75 R248 75 R246 R102 499 AGND R101 499 AGND V4_OUT_B H4_OUT_B B4_OUTN_B B4_OUTP_B G4_OUTN_B G4_OUTP_B R4_OUTN_B R4_OUTP_B R98 75 R96 75 R97 75 AGND AGND ID BIT 1 HORIZONTAL SYNC VERTICAL SYNC NC (ID BIT 3 or DATA CLOCK) 13 14 15 ID BIT 0 SYNC RETURN NC (DDC +5V) BLUE SHIELD GREEN SHIELD RED SHIELD GROUND ID BIT 2 BLUE GREEN RED 12 11 10 9 8 7 6 5 4 3 2 1 P20 13649-020 UG-890 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide Figure 20. Output 4 Rev. 0 | Page 24 of 33 Figure 21. Output 5 Rev. 0 | Page 25 of 33 V H G5_OUTP_A G5_OUTN_A B5_OUTP_A B5_OUTN_A H5_OUT_A L24 K24 K25 K26 L23 V5_OUT_A R5_OUTN_A L25 K23 R5_OUTP_A L26 PBGA-676_27X27 CHANNEL=5 B B G G R SKT1 0 R107 75 R257 75 R255 75 R253 0 R106 75 R256 75 R254 75 R252 R109 499 AGND R108 499 AGND V5_OUT_B H5_OUT_B B5_OUTN_B B5_OUTP_B G5_OUTN_B G5_OUTP_B R5_OUTN_B R5_OUTP_B R105 75 R103 75 R104 75 AGND AGND ID BIT 1 HORIZONTAL SYNC VERTICAL SYNC NC (ID BIT 3 or DATA CLOCK) 13 14 15 ID BIT 0 SYNC RETURN NC (DDC +5V) BLUE SHIELD GREEN SHIELD RED SHIELD GROUND ID BIT 2 BLUE GREEN RED 12 11 10 9 8 7 6 5 4 3 2 1 P21 13649-121 R AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide UG-890 UG-890 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide SKT1 R R H26 R6_OUTP_A H25 R6_OUTN_A R260 49.9 R6_OUTP_B R261 P22 R6_OUTN_B 1 49.9 H24 G G24 G R262 G6_OUTP_A G6_OUTN_A 49.9 2 G6_OUTP_B R263 3 G6_OUTN_B 4 49.9 B B G25 B6_OUTP_A G26 B6_OUTN_A R259 49.9 5 B6_OUTP_B R258 6 B6_OUTN_B 7 49.9 H V 8 H23 G23 9 GND PINS 10 13649-122 PBGA-676_27X27 CHANNEL =6 AGND Figure 22. Output 6 J20 R7_OUTP_B ROS32K243-40ME3 J21 R7_OUTN_B ROS32K243-40ME3 R R J22 G7_OUTP_B SKT1 A23 R7_OUTP_A B23 R7_OUTN_A C23 G7_OUTP_A R266 49.9 ROS32K243-40ME3 R267 49.9 G C22 G G7_OUTN_A R268 49.9 J23 G7_OUTN_B R269 ROS32K243-40ME3 49.9 B22 B7_OUTP_A A22 B7_OUTN_A D23 H7_OUT_A D22 V7_OUT_A 49.9 R264 49.9 H V ROS32K243-40ME3 R110 442 J24 B7_OUTP_B R111 J25 B7_OUTN_B 442 PBGA-676_27X27 CHANNEL=7 ROS32K243-40ME3 J26 H7_OUT_B ROS32K243-40ME3 J27 V7_OUT_B ROS32K243-40ME3 AGND Figure 23. Output 7 Rev. 0 | Page 26 of 33 13649-123 B B R265 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide UG-890 SKT1 A20 R8_OUTP_A R B20 R8_OUTN_A R272 49.9 R273 G G C20 G8_OUTP_A C19 G8_OUTN_A R274 49.9 R275 B B B19 A19 B8_OUTN_A R270 49.9 R271 H8_OUT_A V8_OUT_A R112 442 G8_OUTP_B B8_OUTP_B B8_OUTN_B H8_OUT_B 49.9 H D20 V D19 R8_OUTN_B G8_OUTN_B 49.9 B8_OUTP_A P23 R8_OUTP_B 49.9 2 * PIN SWAP 1 * PIN SWAP 6 * PIN SWAP 5 * PIN SWAP 3 4 7 V8_OUT_B 8 R113 9 442 PBGA-676_27X27 CHANNEL=8 10 11 12 13 14 15 16 17 18 GND PINS 19 20 21 22 23 24 25 AGND Figure 24. Output 8 Rev. 0 | Page 27 of 33 13649-122 R UG-890 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide J28 J30 THRU_SMA_1P ROS32K243-40ME3 ROS32K243-40ME3 J29 J31 THRU_SMA_1N AGND ROS32K243-40ME3 ROS32K243-40ME3 AGND AGND AGND LEODE09STUCD1 25 AGND 24 23 22 21 20 19 18 PINS GND 17 16 15 14 13 12 11 10 9 8 P24 1 THRU_UHD_1P 7 2 THRU_UHD_1N 6 5 3 THRU_UHD_2P 4 4 THRU_UHD_2N 5 6 THRU_UHD_3P 7 THRU_UHD_3N 3 2 1 8 P25 9 10 11 12 13 14 15 16 17 GND PINS 18 19 20 21 22 23 24 13649-021 25 LEODE09STUCD1 AGND Figure 25. Network Analyzer Calibration Paths Rev. 0 | Page 28 of 33 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide VPOS AA2 AA3 AA4 AA5 AA6 AA7 AA8 AA9 AA10 AA11 AA12 AA13 AA14 AA15 AA16 AA17 AA18 AA19 AA20 AA21 AA22 AA23 AB4 AB5 AB19 AB20 AB21 AB22 AB23 AC4 AC5 AC6 AC7 AC8 AC9 AC10 AC11 AC12 AC13 AC14 AC15 AC16 AC17 AC18 AC21 AD9 AD15 AD21 AE9 AE15 AE21 AF9 AF15 AF21 AD8175 Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Positive Power Pins AA1 Y22 Y21 Y20 Y19 Y18 Y17 Y16 Y15 Y14 Y13 Y12 Y11 Y10 Y9 Y8 Y7 Y6 Y5 Y4 Y3 Y2 Y1 W22 W21 W7 W6 W5 W4 V26 V25 V24 V23 V22 V21 V7 V6 V5 V4 U22 U21 U7 U6 U5 U4 T22 T21 T7 T6 T5 T4 R23 R22 R21 R7 R6 R4 P22 P21 P7 P6 P4 P3 P2 Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos G7 G8 G9 G10 G11 G12 G13 G14 G15 G16 G17 G18 G19 G20 G21 G22 H4 H5 H6 H7 H21 H22 J4 J5 J6 J7 J21 J22 J23 K4 K5 K6 K7 K21 K22 L4 L5 L6 L7 L21 L22 M4 M5 M6 M7 M21 M22 M23 M24 M25 M26 N1 N2 N3 N4 N6 N7 N21 N22 P1 Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos Vpos A6 A12 A18 B6 B12 B18 C6 C12 C18 D4 D5 D6 D7 D8 D9 D10 D11 D12 D13 D14 D15 D16 D17 D18 D21 E4 E5 E19 E20 E21 E22 E23 F1 F2 F3 F4 F5 F6 F7 F8 F9 F10 F11 F12 F13 F14 F15 F16 F17 F18 F19 F20 F21 F22 F23 F24 F25 F26 G1 G2 G3 G4 G5 G6 PBGA-676_27X27 SKT1 AD8175_SOCKET AD8175 DIFFERENTIAL CROSSPOINT SWITCH IO VPOS C47 C56 C55 C54 C53 C52 C51 C50 C49 C48 C75 C76 C77 C78 C74 C73 C72 C71 C70 C69 .1UF .1UF .1UF .1UF .1UF .1UF .1UF .1UF .1UF .1UF .01UF .01UF .01UF .01UF .01UF .01UF .01UF .01UF .01UF .01UF VPOS AGND C127 C128 C45 C44 C43 C46 C42 68UF 68UF 1UF 1UF 1UF 1UF 1UF AGND VNEG W8 W9 W10 W11 W12 W13 W14 W15 W16 W17 W18 W19 W20 AA24 AA25 AA26 AB24 AB25 AB26 AC24 AC25 AC26 AD1 AD2 AD3 AD6 AD12 AD18 AD24 AD25 AD26 AE1 AE2 AE3 AE6 AE12 AE18 AE24 AE25 AE26 AF1 AF2 AF3 AF6 AF12 AF18 AF24 AF25 AF26 AD8175 Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Negative Power Pins Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg V20 V19 V18 V17 V16 V15 V14 V13 V12 V11 V10 V9 V8 U20 U19 U18 U17 U16 U15 U14 U13 U12 U11 U10 U9 U8 U3 U2 U1 T20 T19 T18 T17 T16 T15 T14 T13 T12 T11 T10 T9 T8 R26 R25 R24 R20 R19 R18 R17 R16 R15 R14 R13 R12 R11 R10 R9 R8 P20 P19 P18 P17 P16 P15 K3 K8 K9 K10 K11 K12 K13 K14 K15 K16 K17 K18 K19 K20 L8 L9 L10 L11 L12 L13 L14 L15 L16 L17 L18 L19 L20 M8 M9 M10 M11 M12 M13 M14 M15 M16 M17 M18 M19 M20 N8 N9 N10 N11 N12 N13 N14 N15 N16 N17 N18 N19 N20 P8 P9 P10 P11 P12 P13 P14 Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg Vneg A1 A2 A3 A9 A15 A21 A24 A25 A26 B1 B2 B3 B9 B15 B21 B24 B25 B26 C1 C2 C3 C9 C15 C21 C24 C25 C26 D24 D25 D26 E24 E25 E26 H8 H9 H10 H11 H12 H13 H14 H15 H16 H17 H18 H19 H20 J8 J9 J10 J11 J12 J13 J14 J15 J16 J17 J18 J19 J20 J24 J25 J26 K1 K2 PBGA-676_27X27 SKT1 IO AD8175 DIFFERENTIAL CROSSPOINT SWITCH AD8175_SOCKET VNEG C66 C57 C58 C59 C60 C61 C62 C63 C64 C65 C82 C81 C80 C79 C83 C84 C85 C86 C87 C88 .1UF .1UF .1UF .1UF .1UF .1UF .1UF .1UF .1UF .1UF .01UF .01UF .01UF .01UF .01UF .01UF .01UF .01UF .01UF .01UF VNEG 68UF 68UF C38 C39 C40 C37 C41 C126 C125 1UF 1UF 1UF 1UF 1UF AGND Figure 26. VPOS and VNEG Rev. 0 | Page 29 of 33 13649-022 AGND UG-890 13649-023 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide Figure 27. AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ Evaluation Board, Top View 13649-024 UG-890 Figure 28. AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ Evaluation Board, Bottom View Rev. 0 | Page 30 of 33 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide UG-890 ORDERING INFORMATION BILL OF MATERIALS Table 2. Item 1 2 3 Reference Designator A1 to A4 C1, C2, C37 to C46 C3 to C36 Qty 4 12 34 Manufacturer Analog Devices, Inc. Panasonic Yageo Part Number ADR280ARTZ-REEL7 ECJ-1VBOJ105K CC0603KRX7R9BB103 20 22 38 Description ADR280ART-REEL7, SOT-23, SNWD Capacitor, ceramic, chip, 1 μF, 6.3 V, 10%, 0603, X5R Capacitor, ceramic, chip, 10000 pF, 50 V, 0603, X7R (0.01 μF) Capacitor, ceramic, chip, 0.1 μF, 25 V, 10%, 0508, X7R Capacitor, ceramic, chip, 0.01 μF, 16 V, 0402 (10,000 pF) Capacitor, ceramic, chip, 0.01 μF, 50 V, 10%, 0805, X7R 4 5 6 7 8 9 10 11 12 13 14 C47 to C66 C67 to C88 C89 to C122, C129 to C132 C123 to C128 FID1 to FID6 FID7 to FID9 J1 J2, J4, J6 J3 J5 J7 Panasonic Panasonic Panasonic ECY-29RE104KV ECJ-0EBIC103K ECJ-2YB1H104K 6 6 3 1 3 1 1 1 Capacitor, chip, tantalum, 68 μF, 20 V, 7343, 10% 50 mil, pad 40 mil pad Connector, banana jack, yellow Connector, banana jack, green Connector, banana jack, red Connector, banana jack, black Connector, SMA, female, PC mount T495X686K020ATE150 J8 to J31 24 Connector, SMA, right angle jack 16 17 18 19 20 JMP1 to JMP40 P1 P2 to P9 P10 to P13, P22 P14, P15, P23 to P25 40 1 8 5 5 Socket, header, 3-pin Connector, 34-pin, straight header Connector, 15-pin, right angle, D plug (HD) CAT5, RJ45, jack Connector, 8 position, UHD, header 21 22 23 24 P16 to P21 Q1 to Q16 R1, R110 to R113 R2 to R4, R10 to R12, R16 to R18, R22 to R24, R26 to R28, R35 to R37, R41 to R43, R47 to R49 R5 to R9, R13 to R15, R19 to R21, R25 R29 to R34 R50 to R58, R63 to R71, R76 to R84, R89 to R91, R96 to R98, R103 to R105 R59, R60, R72, R73, R85, R86, R92, R93, R99, R100, R106, R107 R61, R62, R74, R75, R87, R88, R94, R95, R101, R102, R108, R109 R114 to R119, R125 to R130, R134 to R139, R143 to R148, R152 to R157, R161 to R166, R170 to R175, R179 to R184, R198 to R221, R158 to R160 6 16 5 24 Connector, DB, 15-pin, right angle, D receptacle Transistor, PNP, low, 2N3906G TO92 Resistor, chip, 1%, 1/10 W, 0603, 442 Ω Resistor, chip, 1/10 W, 0603, 80.6 Ω Kemet Do not include Do not include Johnson/Emerson Johnson/Emerson Johnson/Emerson Johnson/Emerson Pasternack Enterprise Rosenberger of North America FCI 3M Tyco/AMP Do not include W. L. Gore & Associates, Inc. Norcomp On Semi Panasonic Panasonic 15 12 Resistor, chip, 1%, 1/10 W, 0603, 37.4 Ω Yageo RC0603FR-0737R4L 12 36 Resistor, chip, 1%, 1/10 W, 0603, 130 Ω Resistor, chip, 1%, 1/10 W, 0603, 75 Ω Panasonic Panasonic ERJ-3EKF1300V ERJ-3EKF75R0V, full reel 12 Resistor, chip, 5%, 1/10 W, 0603, 0 Ω Panasonic ERJ-3GEY0R00V 24 Resistor, chip, 1%, 1/10 W, 0603, 499 Ω Panasonic ERJ-3EKF4990V 90 Resistor, chip, 1%, 1/16 W, 0402, 49.9 Ω Panasonic ERJ-2RKF49R9X, full reel 25 26 27 28 29 30 Rev. 0 | Page 31 of 33 108-0907-001 108-0904-001 108-0902-001 108-0903-001 PE4117 32K243-40ME3 69190-403HLF N2534-6002RB 5749767-1 HFN1158-G-KES1 181-015-213R171 2N3906G ERJ-3EKF4420V ERJ-3EKF80R6V UG-890 Item 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide Reference Designator R120 to R124, R131 to R133, R140 to R142, R149 to R151, R158 to R160, R167 to R169, R176 to R178, R185 to R197 R222 to R257 Qty 36 Description Resistor, chip, 5%, 1/16 W, 0402, 100 Ω Manufacturer Panasonic Part Number ERJ-2GEJ101X, full reel 36 Resistor, chip, 1%, 1/16 W, 0402, 75 Ω Panasonic R276 to R292 R334, R335, R341, R344, R348, R349, R355, R358, R362 to R364, R367, R293 to R299, R301, R302, R304, R313, R316, R320, R321, R327, R330 R300, R317, R331, R345, R359, R368, R377, R386 R303, R305, R314, R315, R328, R329, R342, R343, R356, R357, R365, R366, R374, R375, R383, R384 R306, R318, R332, R346, R360, R369, R378, R387 R307, R319, R333, R347, R361, R370, R379, R388 R309 to R311, R323 to R325, R337 to R339, R351 to R353 R391 to R393, R397, R398, R401, R402, R404 to R408, R412, R413, R416, R417, R419 to R423, R427, R428, R431, R432, R434, R435 R394 to R396, R409 to R411, R424 to R426 R399, R400, R403, R414, R415, R418, R429, R430, R433 SKT1 TP1 TP2 TP3 TP4 U1 to U8 U9 to U12 U13 to U15 17 38 Resistor, chip, 1%, 1/8 W, 0805, 10 kΩ Resistor, chip, 1%, 1/8 W, 0805, 1 kΩ Panasonic Panasonic ERJ-2RKF75R0X, full reel ERJ-6ENF1002V ERJ-6ENF1001V, full reel 8 Resistor, chip, 1%, 1/8 W, 0805, 4.42 kΩ Panasonic ERJ-6ENF4421V 16 Resistor, chip, 1%, 1/8 W, 0805, 6.98 kΩ Panasonic ERJ-6ENF6981V 8 Resistor, chip, 1%, 1/8 W, 0805, 499 Ω Panasonic ERJ-6ENF4990V 8 Resistor, chip, 0.1%, 1/10 W, 0805, 620 Ω Panasonic ERA-6YEB621V 12 Resistor, chip, 1%, 1/10 W, 0603, 53.6 Ω Panasonic ERJ-6EKF53R6V 27 Resistor, chip, 5%, 1/8 W, 0805, 300 Ω Panasonic ERJ-6GEYJ301, full reel 9 Resistor, chip, 1%, 1/8 W, 0805, 24.9 Ω Panasonic ERJ-6ENF24R9V 9 Resistor, chip, 1%, 1/8 W, 0805, 150 Ω Panasonic ERJ-6ENF1500V 1 1 1 1 1 8 4 3 AD8175 differential crosspoint switch matrix Test point, yellow Test point, blue Test point, white Test point, green LFCSP-24, AD8147ACPZ-REEL7 ADA4861, IC, triple, 730 MHz, op amp AD8003ACPZ, IC, triple, 1.5 GHz, op amp Analog Devices, Inc. Component Corp Component Corp Component Corp Component Corp Analog Devices, Inc. Analog Devices, Inc. Analog Devices, Inc. Do not include TP-104-01-04 TP-104-01-06 TP-104-01-09 TP-104-01-05 AD8147ACPZ-REEL7 ADA4861-3YRZ AD8003ACPZ-REEL7 Rev. 0 | Page 32 of 33 AD8175-EVALZ/AD8176-EVALZ/AD8177-EVALZ/AD8178-EVALZ User Guide UG-890 NOTES ESD Caution ESD (electrostatic discharge) sensitive device. Charged devices and circuit boards can discharge without detection. Although this product features patented or proprietary protection circuitry, damage may occur on devices subjected to high energy ESD. Therefore, proper ESD precautions should be taken to avoid performance degradation or loss of functionality. Legal Terms and Conditions By using the evaluation board discussed herein (together with any tools, components documentation or support materials, the “Evaluation Board”), you are agreeing to be bound by the terms and conditions set forth below (“Agreement”) unless you have purchased the Evaluation Board, in which case the Analog Devices Standard Terms and Conditions of Sale shall govern. Do not use the Evaluation Board until you have read and agreed to the Agreement. Your use of the Evaluation Board shall signify your acceptance of the Agreement. This Agreement is made by and between you (“Customer”) and Analog Devices, Inc. (“ADI”), with its principal place of business at One Technology Way, Norwood, MA 02062, USA. Subject to the terms and conditions of the Agreement, ADI hereby grants to Customer a free, limited, personal, temporary, non-exclusive, non-sublicensable, non-transferable license to use the Evaluation Board FOR EVALUATION PURPOSES ONLY. Customer understands and agrees that the Evaluation Board is provided for the sole and exclusive purpose referenced above, and agrees not to use the Evaluation Board for any other purpose. Furthermore, the license granted is expressly made subject to the following additional limitations: Customer shall not (i) rent, lease, display, sell, transfer, assign, sublicense, or distribute the Evaluation Board; and (ii) permit any Third Party to access the Evaluation Board. As used herein, the term “Third Party” includes any entity other than ADI, Customer, their employees, affiliates and in-house consultants. The Evaluation Board is NOT sold to Customer; all rights not expressly granted herein, including ownership of the Evaluation Board, are reserved by ADI. CONFIDENTIALITY. This Agreement and the Evaluation Board shall all be considered the confidential and proprietary information of ADI. Customer may not disclose or transfer any portion of the Evaluation Board to any other party for any reason. Upon discontinuation of use of the Evaluation Board or termination of this Agreement, Customer agrees to promptly return the Evaluation Board to ADI. ADDITIONAL RESTRICTIONS. Customer may not disassemble, decompile or reverse engineer chips on the Evaluation Board. Customer shall inform ADI of any occurred damages or any modifications or alterations it makes to the Evaluation Board, including but not limited to soldering or any other activity that affects the material content of the Evaluation Board. Modifications to the Evaluation Board must comply with applicable law, including but not limited to the RoHS Directive. TERMINATION. ADI may terminate this Agreement at any time upon giving written notice to Customer. Customer agrees to return to ADI the Evaluation Board at that time. LIMITATION OF LIABILITY. THE EVALUATION BOARD PROVIDED HEREUNDER IS PROVIDED “AS IS” AND ADI MAKES NO WARRANTIES OR REPRESENTATIONS OF ANY KIND WITH RESPECT TO IT. ADI SPECIFICALLY DISCLAIMS ANY REPRESENTATIONS, ENDORSEMENTS, GUARANTEES, OR WARRANTIES, EXPRESS OR IMPLIED, RELATED TO THE EVALUATION BOARD INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTY OF MERCHANTABILITY, TITLE, FITNESS FOR A PARTICULAR PURPOSE OR NONINFRINGEMENT OF INTELLECTUAL PROPERTY RIGHTS. IN NO EVENT WILL ADI AND ITS LICENSORS BE LIABLE FOR ANY INCIDENTAL, SPECIAL, INDIRECT, OR CONSEQUENTIAL DAMAGES RESULTING FROM CUSTOMER’S POSSESSION OR USE OF THE EVALUATION BOARD, INCLUDING BUT NOT LIMITED TO LOST PROFITS, DELAY COSTS, LABOR COSTS OR LOSS OF GOODWILL. ADI’S TOTAL LIABILITY FROM ANY AND ALL CAUSES SHALL BE LIMITED TO THE AMOUNT OF ONE HUNDRED US DOLLARS ($100.00). EXPORT. Customer agrees that it will not directly or indirectly export the Evaluation Board to another country, and that it will comply with all applicable United States federal laws and regulations relating to exports. GOVERNING LAW. This Agreement shall be governed by and construed in accordance with the substantive laws of the Commonwealth of Massachusetts (excluding conflict of law rules). Any legal action regarding this Agreement will be heard in the state or federal courts having jurisdiction in Suffolk County, Massachusetts, and Customer hereby submits to the personal jurisdiction and venue of such courts. The United Nations Convention on Contracts for the International Sale of Goods shall not apply to this Agreement and is expressly disclaimed. ©2015 Analog Devices, Inc. All rights reserved. Trademarks and registered trademarks are the property of their respective owners. UG13649-0-10/15(0) Rev. 0 | Page 33 of 33
