MAX11198EVKIT#

Evaluates: MAX11198 MAX11198 Evaluation Kit General Description The MAX11198 evaluation kit (EV kit) provides a proven design to evaluate the MAX11198 of 16-bit, 2-channel, 2Msps, fully differential simultaneously sampling SAR ADCs with an internal reference. The EV kit includes an evaluation board and a graphical user interface (GUI) that provides communication from the target device to the PC through a ZedBoard™ with a Xilinx Zynq® -7000 SOC. The EV kit is connected to a ZedBoard through a low-pincount FMC connector and a ZedBoard connected to the PC through an Ethernet port. The EV kit includes Windows XP®, Windows® 7 and Windows 8 compatible software for exercising the features of the IC. The EV kit GUI allows different sample sizes, adjustable sampling rates, and graphing software that includes the FFT and histogram of the sampled signals. The EV kit can be powered by +12V supply from ZedBoard or by an external power supply. The EV kit has two DC-DC converters and 5V LDO which provide all necessary supplies for operation with ZedBoard. The MAX11198 EV kit comes installed with a MAX11198ATE+ in a 16-pin, 2mm x 3mm TQFN-EP package. The EV kit aims to be used with an external resolver or encoder to monitor and measuring degrees of rotation or absolute position of the rotor at any given moment. Windows and Windows XP are registered trademarks and registered service marks of Microsoft Corporation. ZedBoard is a trademark of Avnet Corp. Zynq is a registered trademark of Xilinx, Inc.. 319-100084; Rev 0; 10/17 Features ●● 50MHz SPI Clock Capability through FMC Connector ●● Various Sample Sizes and Sample Rates ●● Collects Up to 1 Million Samples ●● Time Domain, Frequency Domain, and Histogram Plotting ●● Sync In and Sync Out for Coherent Sampling ●● On-Board Input Buffers: MAX44242 and MAX44205 (Fully Differential) ●● On-Board External Voltage Reference: MAX6126 ●● Proven PCB Layout ●● Fully Assembled and Tested ●● Windows XP, Windows 7, and Windows 8-Compatible Software Ordering Information appears at end of data sheet. MAX11198 Evaluation Kit Evaluates: MAX11198 EV Kit Photo www.maximintegrated.com Maxim Integrated │  2 MAX11198 Evaluation Kit Evaluates: MAX11198 System Block Diagram 1 SIN+ 2 COS- 4 SHIELDS 5 EXCITATION - 6 EXCITATION + 7 MAX17552 (100mA DC-DC) POWER JACK +12V +12V +5V EXT OVDD +6.5V MAX44205 VADJ (1.8V, 2.5V, or 3.3V) IN1+ REFIN/2 REFIN IN1REFIN/2 AVDD OVDD MAX11198 IN2+ 3 COS+ +6.5V VREF TERMINAL 2x MAX44242 BLOCK SIN- MAX17552 (100mA DC-DC) MAX15006B EXT REF RESOLVER / ENCODER INPUTS -6.5V IN2- AGND SPI0 (CNVST, SCLK0, DOUT1, DOUT2) FMC DGND -6.5V +6.5V +5V (4V TO 8V, 1kHz TO 10kHz) MAX6126A41+ VREF +6.5V MAX44242 MAX44242 -6.5V 2kΩ 50Ω MAX5316 10nF SPI1 (CSb, SCLK1, DAC_DIN, DAC_DOUT) MAX11198 EV Kit Files FILE MAX11198EVKitSetupV1.0.exe Boot.bin www.maximintegrated.com DESCRIPTION Application Program (GUI) ZedBoard firmware (SD card to boot Zynq) Maxim Integrated │  3 MAX11198 Evaluation Kit Evaluates: MAX11198 Quick Start 5) Connect the EV Kit FMC connector to the ZedBoard FMC connector. Gently press them together. Required Equipment ●● MAX11198 EV kit (includes SD card with firmware) ●● ZedBoard FPGA platform (optional – NOT INCLUDED with EV Kit) ●● Function generator or an external resolver (optional) ●● Windows XP, Windows 7 or Windows 8 PC with an Ethernet port Note: In the following section(s), software-related items are identified by bolding. Text in bold refers to items directly from the EV system software. Text in bold and underline refers to items from the Windows operating system. Procedure The EV kit is fully assembled and tested. Follow the steps below to verify board operation: 1) Visit www.maximintegrated.com/evkitsoftware to download the latest version of the EV kit software, MAX11198EVK.ZIP. Save the EV kit software to a temporary folder and uncompress the ZIP file. 2) Install the EV kit software on your computer by running the MAX11198_EVKitSetupV1.0.exe program inside the temporary folder. The program files are copied to your PC and icons are created in the Windows Start | Programs menu. 3) Connect the Ethernet cable from the PC to the ZedBoard and configure the Internet Protocol Version 4 (TCP/Ipv4) properties in the local area Connection to IP address 192.168.1.2 and subnet Mask to 255.255.255.0. 4) Verify that the ZedBoard SD card contains the Boot. bin file for the MAX11198 EV Kit 6) Verify that all jumpers are in their default positions for the ZedBoard (Table 1) and EV kit board (Table 2). 7) Connect the 12V power supply to the ZedBoard. Leave the Zedboard powered off. 8) Enable the ZedBoard power supply by sliding SW8 to ON and connect the +12V adapter to the EV kit. 9) Start the EV kit software by opening its icon in the Start | Programs menu. The EV kit software appears as shown in Figure 1. From the Device menu select FPGA. Verify that the lower left status bar indicates the EV Kit hardware is Connected. The following configuration is used to verify functionality of simultaneous sampling of the same signal from signal generator applied to both channels. 10) Connect the positive terminal of the function generator to the AIN0D+ (TP1) test point on the EV kit. Connect the negative terminal of the function generator to the AIN0D- (TP2) test point on the EV kit. 11) Configure the signal source to generate a 100Hz, 1VP-P sinusoidal wave with +1V offset. 12) Turn on the function generator. 13) Click on the Scope tab. 14) Check the Remove DC Offset checkbox to remove the DC component of the sampled data. 15) Click the Capture button to start the data analysis. 16) The EV kit software appears as shown in Figure 1. 17) Verify the frequency is approximately 100Hz is displayed on the right. The scope image has buttons in the upper right corner that allow zooming in to detail. Table 1. ZedBoard Jumper Settings JUMPER SHUNT POSITION 1-2 Select 3.3V for VADJ (OVDD) J18 3-4 Select 2.5V for VADJ (OVDD) 5-6 Select 1.8V for VADJ (OVDD) 2-3 1-2 1-2 2-3 2-3 Boot from SD card NA SD card installed JP11 JP10 JP9 JP8 JP7 JP10 J12 J20 NA SW8 OFF www.maximintegrated.com DESCIPTION Connected to 12V wall adapter ZedBoard power switch, OFF while connecting boards Maxim Integrated │  4 MAX11198 Evaluation Kit Evaluates: MAX11198 Table 2. MAX11198 Board Jumper Settings HEADER J2 J3 J4 J5 J6 J7 J8 J9 J10 J11 J12 J13 JUMPER POSITION Open* 1-2 Open* 1-2 Open* 1-2 Open* J22 J23 J24 J25 J26 Use differential input to Channel 1 Use single-ended input to Channel 1 referenced to GND Use differential input to Channel 2 Use single-ended input to Channel 2 referenced to GND TP2 is disconnected to Channel 1 input TP2 is connected to Channel 1 input TP2 is disconnected to Channel 2 input 1-2 TP2 is connected to Channel 2 input 1-2* Use U1.A as input buffer to Channel 1 negative input 2-3 Bypass U1.A 1-2* Use U1.B as input buffer to Channel 1 positive input 2-3 Bypass U1.B 1-2* Use U2.A as input buffer to Channel 2 negative input 2-3 Bypass U2.A 1-2* Use U2.B as input buffer to Channel 2 positive input 2-3 Bypass U2.B Open* 1-2 Open* 1-2 Open For independent Channel 1 and Channel 2 measurements Short IN1+ to IN2+ for single input to both channels For independent Channel 1 and Channel 2 measurements Short IN1- to IN2- for single input to both channels Use J12.2 to supply an external voltage to AVDD 1-2* Use onboard +5V to AVDD Open* Use an external reference 1-2* Generates REFIN/2 for differential buffers (U3, U4) Open* Disconnect U14 output from J13 and U15. U15 uses U5 internal reference to generate REFIN/2 for U3 and U4 differential buffers. 1-2* Connect U14 to J13 and U15. U15 generates REFIN/2 = 2.048V for U3 and U4 differential buffers. J14 J15 DESCRIPTION 1-2 Use external OVDD 2-3* Use OVDD voltage from ZedBoard. See J18 selection in Table 1. 1-2* Enable U12 and U13 DC-DC converters to generate ±6.5V 2-3 Disable U12 and U13; it is also recommended to open J24 and J25 1-2* Use +12V from ZedBoard to power EV kit Open Use an external +12V supply to J20 or J21 1-2* Open 1-2* Use -6.5V from U13 Use an external -6.5V to TP21 Use +6.5V from U12 Open Use an external +6.5V to TP22 Open* Disconnect U7 output from TP2 1-2 Connect U7 output to TP2 *Default position. www.maximintegrated.com Maxim Integrated │  5 MAX11198 Evaluation Kit General Description of Software The main window of the EV kit software contains five tabs: System, Scope, DMM, Histogram, and FFT. The System tab provides control for the ADC configuration including calibration and single data capture. The other four tabs are used for evaluating the data captured by the ADC. System Tab The System tab allows to select Sample Rate, Number of Samples, Clock Source for coherent sampling and for SPI interface, as well as EV kit Device resolution from Evaluates: MAX11198 corresponding pulldown menu. There is a block diagram of the EV kit and Calibration section for convenience. The Read Data information is displayed on the right, which shows the data in both voltage and LSB, see Figure 1. Sample Rate (SPS) To select the desired data rate choose the Sample Rate (SPS) pulldown menu. The sampling rate is available from 1000sps to 2000000sps. Number of Samples The Number of Samples pulldown menu allows choosing from 1 up to 1048576 samples to be captured. Figure 1. EV Kit Software (Configuration Tab) www.maximintegrated.com Maxim Integrated │  6 MAX11198 Evaluation Kit Reference Voltage The Reference Voltage selection should match with the jumper settings refer to Table 2. A user can select either internal or external reference voltage. The internal reference is fixed to 2.5V. The external reference can be from 2.5V to 4.75V. Use “+” or “-″ buttons to adjust the actual voltage reference, or simply type in a new value. ADC Calibration The ADC Calibration section allows to calibrate each channel independently. Scope Tab Evaluates: MAX11198 of Samples, Display Unit, Average Samples, and Resolution Selection can be set in this tab if they were not appropriately adjusted in other tabs. The Display Unit pull-down list allows counts in LSB and voltages in V, mV, or µV. Once the desired configuration is set, click on the Capture button. The right side of the tab sheet displays details of the waveform, such as average, standard deviation, maximum, minimum, and fundamental frequency for each channel as shown in Figure 2. To save the captured data to a file, select Options > Save Graph > Scope. This saves the setting on the left and the data captured to a CSV file. The Scope tab sheet is used to capture data and display it in the time domain. The desired Sampling Rate, Number Figure 2. EV Kit Software (ScopeTab) www.maximintegrated.com Maxim Integrated │  7 MAX11198 Evaluation Kit DMM Tab The DMM tab sheet provides the typical information as a digital multimeter. Once the desired configuration is set, click on the Capture button. Figure 3 displays the results shown by the DMM tab when no signal is applied to both channels. Evaluates: MAX11198 To save the histogram data to a file, go to Options > Save Graph > Histogram. This saves the setting on the left and the histogram data captured to a CSV file. FFT Tab The Histogram tab sheet is used to show the histogram of the data. Sampling rate and number of samples can also be set in this tab if they were not appropriately adjusted in other tabs. Once the desired configuration is set, click on the Capture button. The right side of the tab sheet displays details of the histogram such as average, standard deviation, maximum, minimum, peak-to-peak noise, effective resolution, and noise-free resolution as shown in Figure 4. The FFT tab sheet is used to display the FFT of the data. The Sample Rate, Number of Samples, Resolution Selection, and type Window Function can be set as desired. To calculate the Adjusted Input Signal frequency for Coherent Sampling, type in the Input Signal frequency in Hertz and GUI automatically calculates the master clock needs to be applied for coherent sampling and vice versa. Once the preferred configuration is set, click on the Capture button. The right side of the tab displays the performance based on the FFT, such as fundamental frequency, SNR, SINAD, THD, SFDR, ENOB, and Noise Floor as shown in Figure 5. The histogram tab is enabled at default. Using the histogram will slow down the GUI response. To disable it, check the Disable Histogram box. To save the FFT data to a file, go to Options > Save Graph > FFT. This saves the setting on the left and the FFT data captured to a CSV file. Histogram Tab Figure 3. EV Kit Software (DMM Tab) www.maximintegrated.com Maxim Integrated │  8 MAX11198 Evaluation Kit Evaluates: MAX11198 Figure 4. EV Kit Software (Histogram Tab) Figure 5. EV Kit Software (FFT Tab) www.maximintegrated.com Maxim Integrated │  9 MAX11198 Evaluation Kit Evaluates: MAX11198 When coherent sampling is needed, this tab allows the user to calculate the input signal applied to the board. Adjust the input frequency of the low-jitter clock to the value as shown in the Adjusted Input Signal (Hz) and apply it to the EV KIT SYNC_CLK_IN connector. See the Sync Input and Sync Output section before using this feature. Figure 6 shows the setup Maxim Integrated uses to capture data for coherent sampling. Figure 7 shows the coherent FFT signal. Use the jumper settings from Table 2 for proper configurations. The low-jitter clock is synchronized with the signal generator at 10MHz from the ZedBoard. To achieve coherent sampling, click on the Calculate button and enter the Adjusted Input Signal (Hz) into low-jitter clock. Timing for all SPI timing and sampling rate are based off the system clock. User-Supplied SPI To evaluate the EV kit with a user-supplied SPI bus, disconnect the board from the ZedBoard. Apply the usersupplied SPI signals to SCLK, CNVST, DOUT1, and DOUT2 to J17. Make sure the return ground from J17.15 is connected to master ground. FMC Interface The users should confirm compatibility of pin-usage between their own FMC implementation and that of the MAXIM EV kit before connecting the MAXIM EV kit to a different system with FMC connectors. LOW JITTER CLOCK OUT ~100MHz ZEDBOARD 10MHz _ AIN1- + AIN1+ _ AIN2- + AIN2+ SIGNAL GENERATOR PC DCLK_IN MAX11198EVKIT# ETHERNET CABLE Figure 6. EV Kit Coherent Sampling Setup www.maximintegrated.com Maxim Integrated │  10 MAX11198 Evaluation Kit Evaluates: MAX11198 Figure 7. MAX11198 EV Kit Coherent Sampling (FFT Tab) External OVDD Power Supply An external OVDD voltage can supply to TP12 in range from 1.8V to 3.6V. The J15 shunt should be set in 1-2 position. User-Supplied Power Supply The EV kit receives power from ZedBoard or from a single DC source of 12V, 200mA through a J26 power jack. The two MAX17552 DC-DC converters generate +6.5V and -6.5V for the buffers, U1 and U2, and differential amplifiers, U3 and U4. The +6.5V power is then regulated down to a +5V by MAX15006B for U5. See the EV kit schematic for details. User can supply an external +6.5V to TP22 and -6.5V to TP21 to reduce the influence of DC-DC converter switching frequency. In this case, the J23, J24 and J25 shunts must be removed. Sync Input and Sync Output (for coherent sampling) Sync Input and Sync Output is applicable to the FPGA (ZedBoard) and is not used in Standalone mode. Sync Input and Sync Output The SYNC_IN SMA accepts an approximate 100MHz waveform signal to generate the system clock of the ZedBoard. For maximum performance, use a low-jitter clock that syncs to the user’s analog function generator. The SYNC_OUT SMA outputs a 10MHz square waveform that syncs to the user’s analog function generator. Both options are used for coherent sampling of the IC. Use only one option at a time. The relationship between fIN, fS, NCYCLES, and MSAMPLES is given as follows: N fIN = CYCLES f S M SAMPLES ADC Input Amplifiers The analog front-end conditioner for each channel includes the input low-pass filter (1k resistor and 1000pF capacitor), the MAX44242 input buffer and the MAX44205 fully differential amplifier. where: fIN = Input frequency fS = Sampling frequency NCYCLES = Prime number of cycles in the sampled set MSAMPLES = Total number of samples www.maximintegrated.com Maxim Integrated │  11 MAX11198 Evaluation Kit Evaluates: MAX11198 MAX11198 EV Kit Bill of Materials ITEM REF DES DNI/DNP QTY 1 C1, C100, C101 - 3 TPSC226K025R0275 AVX VALUE DESCRIPTION 22UF CAPACITOR; SMT; 6032; TANTALUM; 22uF; 25V; 10%; TPS; -55degC to +125degC 2 C2-C5, C8-C11 - 8 GRM1885C1H102JA01; C1608C0G1H102J080 MURATA; TDK 1000PF CAPACITOR; SMT (0603); CERAMIC CHIP; 1000PF; 50V; TOL=5%; TG=-55 DEGC TO +125 DEGC 3 C6, C7, C14, C15, C31, C35, C57, C67, C116 - 9 GRM21BR61E106K; C2012X5R1E106K125AB; C2012X5R1E106K MURATA/TDK 10UF CAPACITOR; SMT (0805); CERAMIC CHIP; 10UF; 25V; TOL=10%; MODEL=; TG=-55 DEGC TO +125 DEGC; TC=X5R 4 C12, C13, C16-C19, C28, C29, C32, C33, C36, C37, C39, C40, C55, C56, C61, C65, C70, C73, C78, C81, C82, C84, C115 - 25 GRM188R72A104KA35; CC0603KRX7R0BB104 MURATA; TDK 0.1UF CAPACITOR; SMT (0603); CERAMIC CHIP; 0.1UF; 100V; TOL=10%; TG=-55 DEGC TO +125 DEGC; TC=X7R 5 C20-C23 - 4 GRM1555C1H102JA01; C1005C0G1H102J050 MURATA; TDK 1000PF CAPACITOR; SMT (0402); CERAMIC CHIP; 1000PF; 50V; TOL=5%; TG=-55 DEGC TO +125 DEGC 6 C30, C34 - 2 TMK212BBJ106KG-T; CL21A106KAFN3N TAIYO YUDEN 10UF CAPACITOR; SMT (0805); CERAMIC CHIP; 10UF; 25V; TOL=10%; MODEL=; TG=-55 DEGC TO +85 DEGC; TC=X5R 7 C38, C54, C74-C77, C85, C114 - 8 UMK107AB7105KA TAIYO YUDEN 1UF CAPACITOR; SMT (0603); CERAMIC CHIP; 1UF; 50V; TOL=10%; TG=-55 DEGC TO +125 DEGC; TC=X7R 8 C41, C42 - 2 C0402H102J5GAC KEMET 1000PF CAPACITOR; SMT (0402); CERAMIC CHIP; 1000PF; 50V; TOL=5%; MODEL=HT SERIES; TG=-55 DEGC TO +200 DEGC; TC=C0G 9 C43, C46, C48, C51, C52 - 5 C1608X5R1E106M080AC; CL10A106MA8NRNC TDK/SAMSUNG ELECTRONICS 10UF CAPACITOR; SMT (0603); CERAMIC CHIP; 10UF; 25V; TOL=20%; TG=-55 DEGC TO +85 DEGC; TC=X5R 10 C44, C47, C49, C50, C53 - 5 CGA2B3X7R1H104K; C1005X7R1H104K050BB; GRM155R71H104KE14 TDK; MURATA 0.1UF CAPACITOR; SMT (0402); CERAMIC CHIP; 0.1UF; 50V; TOL=10%; TG=-55 DEGC TO +125 DEGC; TC=X7R 11 C45, C58, C59, C71, C72 - 5 GMK212B7105KG TAIYO YUDEN 1.0UF CAPACITOR; SMT (0805); CERAMIC; 1UF; 35V; TOL=10%; MODEL=GMK SERIES; TG=55 DEGC TO +125 DEGC; TC=X7R www.maximintegrated.com MFG PART # MFG NOTES Maxim Integrated │  12 MAX11198 Evaluation Kit Evaluates: MAX11198 MAX11198 EV Kit Bill of Materials (continued) ITEM REF DES DNI/DNP QTY MFG PART # MFG VALUE DESCRIPTION NOTES CAPACITOR; SMT (0603); CERAMIC CHIP; 0.01UF; 50V; TOL=5%; MODEL=X7R; TG=-55 DEGC TO +125 DEGC; TC=+/ 12 C62-C64, C68 - 4 C0603X7R500103JNP; C0603C103J5 13 C66 - 1 C0603C101J5GAC; ECJ1VC1H101J; C1608C0G1H101J080AA; GRM1885C1H101JA01 14 C69, C79, C80, C106, C108 - 5 C0603C102K1GAC 15 C102, C103 - 2 C1206C105K3RAC; ECJ3YB1E105K 16 C107, C109 - 2 GRM31CR71E106KA12L; CL31B106KAHNNN 17 C110-C113 - 4 C2012X7R1E475K125AB 18 CON1 - 1 ASP-134604-01 19 D1 - 1 MMSZ5226BS 20 D2 - 1 B0530WS-7-F 21 D3 - 1 MBR0520L FAIRCHILD MBR0520 SEMICONDUCTOR L DIODE, SCHOTTKY, SOD-123, PIV=20V, Vf=0.385V@If=0.5A, If(ave)=0.5A 22 DS1, DS2 - 2 LGL29K-G2J1-24-Z OSRAM LGL29KG2J1-24-Z DIODE; LED; SMARTLED; GREEN; SMT; PIV=1.7V; IF=0.02A 23 GND, TP1, TP3, TP4, TP11, TP13, TP16, TP18TP20, TP23, TP25 - 12 5001 KEYSTONE N/A TEST POINT; PIN DIA=0.1IN; TOTAL LENGTH=0.3IN; BOARD HOLE=0.04IN; BLACK; PHOSPHOR BRONZE WIRE SILVER PLATE FINISH; 24 J1 - 1 OSTVN08A150 ON-SHORE TECHNOLOGY INC. 25 J2-J5, J10-J14, J23-J26 - 13 PCC02SAAN SULLINS 26 J6-J9, J15, J22 - 6 PCC03SAAN SULLINS www.maximintegrated.com KEMET 0.01UF KEMET/PANASONI C/TDK/MURATA 100PF CAPACITOR; SMT (0603); CERAMIC CHIP; 100PF; 50V; TOL=5%; MODEL=C0G; TG=-55 DEGC TO +125 DEGC; TC=COG CAPACITOR; SMT (0603); CERAMIC CHIP; 1000PF; 100V; TOL=10%; MODEL=C0G; TG=55 DEGC TO +125 DEGC; TC= CAPACITOR; SMT (1206); CERAMIC CHIP; KEMET/PANASONI 1UF 1UF; 25V; TOL=10%; MODEL=X7R; TG=-55 C DEGC TO +125 DEGC; TC=+/MURATA; CAPACITOR; SMT (1206); CERAMIC CHIP; SAMSUNG 10UF 10UF; 25V; TOL=10%; TG=-55 DEGC TO +125 ELECTRONICS DEGC; TC=X7R CAPACITOR; SMT (0805); CERAMIC CHIP; TDK 4.7UF 4.7UF; 25V; TOL=10%; MODEL=; TG=-55 DEGC TO +125 DEGC; TC=X7R CONNECTOR; MALE; SMT; HIGH ASPSAMTEC SPEED/HIGH DENSITY OPEN PIN FIELD 134604-01 TERMINAL ARRAY; STRAIGHT; 160PINS DIODES DIODE; ZNR; SMT (SOD-323); Vz=3.3V; 3.3V INCORPORATED Izm=0.01A DIODE; SCH; SMT (SOD-323); PIV=30V; DIODES B0530WS7-F IF=0.5A INCORPORATED KEMET 1000PF CONNECTOR; FEMALE; THROUGH HOLE; SCREW TYPE; GREEN TERMINAL BLOCK; RIGHT ANGLE; 8PINS CONNECTOR; MALE; THROUGH HOLE; PCC02SA BREAKAWAY; STRAIGHT THROUGH; 2PINS; AN 65 DEGC TO +125 DEGC CONNECTOR; MALE; THROUGH HOLE; PCC03SA BREAKAWAY; STRAIGHT THROUGH; 3PINS; AN 65 DEGC TO +125 DEGC OSTVN08 A150 Maxim Integrated │  13 MAX11198 Evaluation Kit Evaluates: MAX11198 MAX11198 EV Kit Bill of Materials (continued) ITEM REF DES DNI/DNP QTY MFG PART # MFG VALUE DESCRIPTION NOTES CONNECTOR; FEMALE; THROUGH HOLE; 5-1814832TYCO CONN SOCKET SMA STR DIE CAST PCB; 1 STRAIGHT; 5PINS SULLINS CONNECTOR; MALE; THROUGH HOLE; PBC15SA ELECTRONICS BREAKAWAY; STRAIGHT; 15PINS; -65 DEGC AN CORP. TO +125 DEGC KLDXCONNECTOR; FEMALE; THROUGH HOLE; KYCON 0202-B DC POWER JACK; RIGHT ANGLE; 3PINS CONNECTOR; FEMALE; THROUGH HOLE; 2.54MM PITCH; SIDE WIRE ENTRY TE CONNECTIVITY 282834-2 STACKING TERMINAL BLOCK ; STRAIGHT; 2PINS; -40 DEGC TO + 105 DEGC 27 J16, J19 - 2 5-1814832-1 28 J17 - 1 PBC15SAAN 29 J20 - 1 KLDX-0202-B 30 J2 1 - 1 282834-2 31 L1, L2 - 2 LPS5030-224ML COILCRAFT 220UH 32 L3-L6 - 4 XPL2010-333ML COILCRAFT 33UH 33 R1-R4 - 4 CRCW06031M00JN VISHAY DALE 1M VISHAY DALE; PANASONIC 1K INDUCTOR; MAGNETICALLY SHIELDED FERRITE BOBBIN CORE; SMT; 220UH; TOL=+/-20%; 0.5A; -40 DEGC TO +85 DEGC INDUCTOR; SMT; MAGNETICALLY SHIELDED FERRITE BOBBIN CORE; 33UH; TOL=+/-20%; 0.38A RESISTOR; 0603; 1M OHM; 5%; 200PPM; 0.10W; METAL FILM RESISTOR; 0603; 1K; 1%; 100PPM; 0.10W; THICK FILM 34 R5-R8 - 4 CRCW06031001FK; ERJ3EKF1001V 35 R9-R12 - 4 CRCW0603100RFK; ERJ3EKF1000 VISHAY DALE/PANASONIC 100 RESISTOR; 0603; 100 OHM; 1%; 100PPM; 0.10W; THICK FILM 36 R13-R20 - 8 VISHAY TNPW06031K00BE; RG1608PDALE/SUSUMU CO 102-B-T5 LTD. 1K RESISTOR; 0603; 1K OHM; 0.1%; 25PPM; 0.10W; THICK FILM 0.10% 37 R21-R24 - 4 RN73C1J10RBTG; 1614350-2 TE CONNECTIVITY 10 RESISTOR; 0603; 10 OHM; 0.1%; 10PPM; 0.063W; THICK FILM 0.10% 38 R28, R29, R37 - 3 TNPW060310K0BE; RN731JTTD1002B VISHAY DALE/KOA SPEER ELECTRONICS 10K RESISTOR; 0603; 10K OHM; 0.1%; 25PPM; 0.1W; THICK FILM 39 R30-R34, R102, R103 - 7 CRCW060310K0FK; 9C06031A1002FK; ERJ3EKF1002 VISHAY DALE/YAGEO PHICOMP/PANAS ONIC 10K RESISTOR; 0603; 10K; 1%; 100PPM; 0.10W; THICK FILM 40 R35 - 1 CRCW06032K10FK VISHAY DALE 2.1K RESISTOR; 0603; 2.1K; 1%; 100PPM; 0.10W; THICK FILM 41 R36, R66, R69 - 3 CRCW060349R9FK VISHAY DALE 49.9 RESISTOR; 0603; 49.9 OHM; 1%; 100PPM; 0.10W; THICK FILM www.maximintegrated.com Maxim Integrated │  14 MAX11198 Evaluation Kit Evaluates: MAX11198 MAX11198 EV Kit Bill of Materials (continued) ITEM REF DES DNI/DNP QTY 42 R38, R39 - 2 43 R40-R65 - 44 R67, R68, R104 45 MFG VALUE DESCRIPTION NOTES TNPW060310K0BE; RN731JTTD1002B VISHAY DALE/KOA SPEER ELECTRONICS 10K RESISTOR; 0603; 10K OHM; 0.1%; 25PPM; 0.1W; THICK FILM 0.10% 26 ERJ-3EKF28R0V PANASONIC 28 RESISTOR; 0603; 28 OHM; 1%; 100PPM; 0.10W; THICK FILM - 3 CRCW06030000ZS; MCR03EZPJ000; ERJ3GEY0R00 VISHAY DALE/ROHM/PANA SONIC 0 RESISTOR; 0603; 0 OHM; 0%; JUMPER; 0.10W; THICK FILM R94, R95 - 2 CRCW0603191KFK VISHAY DALE 191K 46 R96, R98 - 2 ERJ-3EKF3573 PANASONIC 357K 47 R97, R99 - 2 CRCW060349K9FK; ERJ3EKF4992V VISHAY DALE/PANASONIC 49.9K RESISTOR; 0603; 49.9K OHM; 1%; 100PPM; 0.10W; THICK FILM 48 R100, R101 - 2 CRCW06031003FK; ERJ3EKF1003 VISHAY DALE/PANASONIC 100K RESISTOR; 0603; 100K; 1%; 100PPM; 0.10W; THICK FILM 49 TP2, TP5-TP10, TP12, TP14, TP15, TP17, TP22, TP24 - 13 5000 KEYSTONE N/A TEST POINT; PIN DIA=0.1IN; TOTAL LENGTH=0.3IN; BOARD HOLE=0.04IN; RED; PHOSPHOR BRONZE WIRE SILVER PLATE FINISH; 50 TP21 - 1 5004 KEYSTONE N/A TEST POINT; PIN DIA=0.1IN; TOTAL LENGTH=0.3IN; BOARD HOLE=0.04IN; YELLOW; PHOSPHOR BRONZE WIRE SILVER PLATE FINISH; 51 U1, U2, U7 - 3 MAX44242AUA+ MAXIM 52 U3, U4 - 2 MAX44205 MAXIM 53 U5 - 1 MAX11198 MAXIM MAX1119 8 EVKIT PART-IC; ADC; 16-BIT; 2MSPS; DUAL SIMULTANEOUS SAMPLING SAR ADCS WITH INTERNAL REFERENCE; 16L TQFN 2X3 LEAD PITCH 0.5MM 54 U6 - 1 MAX5316GTG+ MAXIM MAX5316 GTG+ IC; DAC; 16-BIT, +/-1 LSB ACCURACY VOLTAGE OUTPUT DAC WITH SPI INTERFACE; TQFN24-EP 55 U8 - 1 74LVC125APW NXP 74LVC125 APW IC; BUF; QUAD BUFFER/LINE DRIVER WITH 5V TOLERANT INPUT/OUTPUT; 3-STATE; TSSOP14 www.maximintegrated.com MFG PART # RESISTOR; 0603; 191K OHM; 1%; 100PPM; 0.10W; METAL FILM RESISTOR; 0603; 357K OHM; 1%; 100PPM; 0.1W; THICK FILM MAX4424 2AUA+ IC; OPAMP; DUAL OPERATIONAL AMPLIFIER; UMAX8 IC; LOW-POWER; LOW-DISTORTION; FULLY MAX4420 DIFFERENTIAL OPERATIONAL AMPLIFIER; 5 OZ02; PKG. CODE: T1233-4; Maxim Integrated │  15 MAX11198 Evaluation Kit Evaluates: MAX11198 MAX11198 EV Kit Bill of Materials (continued) ITEM REF DES DNI/DNP QTY MFG PART # MFG 56 U12, U13 - 2 MAX17552ATB+ MAXIM 57 U14 - 1 MAX6126A41+ MAXIM 58 U15 - 1 MAX44244AUK+ MAXIM 59 U16, U17 - 2 74LVC2G125DP NXP 60 U18 - 1 93LC66BT-I/OT MICROCHIP 61 U20 - 1 MAX15006BATT+ MAXIM 62 PCB - 1 MAX11198 MAXIM 63 C60 DNP 0 GMK212B7105KG TAIYO YUDEN 64 C104, C105 DNP 0 C0603C102K1GAC KEMET 65 J18 DNP 0 PBC06SAAN SULLINS ELECTRONICS CORP. 66 R25-R27 DNP 0 SEE NOTES VISHAY DALE TOTAL www.maximintegrated.com VALUE DESCRIPTION IC; CONV; ULTRA-SMALL; HIGHMAX1755 EFFICIENCY; SYNCHROMOUS STEP-DOWN 2ATB+ DC-DC CONVERTER; TDFN10-EP IC; VREF; ULTRA-HIGH PRECISION; ULTRAMAX6126 LOW NOISE; SERIES VOLTAGE A41 REFERENCE; UMAX8 MAX4424 IC; OPAMP; 36V; PRECISION; LOW-POWER; 4AUK+ 90UA; SINGLE OP AMP; SOT23-5 74LVC2G IC; DRV; DUAL BUS BUFFER/LINE DRIVER; 3STATE; TSSOP8 125DP IC; EPROM; 4K MICROWIRE SERIAL 93LC66BTI/OT EEPROM; SOT23-6 IC; VREG; ULTRA-LOW QUIESCENTMAX1500 CURRENT LINEAR REGULATOR; TDFN6-EP 6BATT+ 3X3 PCB PCB:MAX11198 CAPACITOR; SMT (0805); CERAMIC; 1UF; 1.0UF 35V; TOL=10%; MODEL=GMK SERIES; TG=55 DEGC TO +125 DEGC; TC=X7R CAPACITOR; SMT (0603); CERAMIC CHIP; 1000PF 1000PF; 100V; TOL=10%; MODEL=C0G; TG=55 DEGC TO +125 DEGC; TC= CONNECTOR; MALE; THROUGH HOLE; PBC06SA BREAKAWAY; STRAIGHT; 6PINS; -65 DEGC AN TO +125 DEGC RESISTOR; 0603; 20 OHM; 1%; 100PPM; 20 0.10W; THICK FILM NOTES - 251 Maxim Integrated │  16 www.maximintegrated.com J1 OSTVN08A150 1 SIN2 SIN+ 3 COS4 COS+ 5 SHIELDS 6 EXCITATION7 EXCITATION+ 8 1 + C1 22UF 2 1 2 1M R2 R1 1M 1 J2 IN J26 2 J3 1 2 DAC_OUT_BUFF 1 2 1M R4 1M R3 J4 TP1 TP2 1 2 J5 R7 R6 R5 R8 1K 1K 1K 1K C4 1000PF C3 1000PF C2 1000PF C5 1000PF 4 IN 7 +6.5V 1000PF IN -6.5V OUTB U1 MAX44242AUA+ 1000PF 100 100 8 INB+ 1000PF C9 C13 0.1UF C15 10UF J9 -6.5V C17 0.1UF IN 3 2 1 3 2 1 3 2 1 3 2 1 C16 0.1UF PLACE CLOSE TO VDD AND VSS PINS OF U1 C7 10UF 100 R10 INB- +6.5V U2 MAX44242AUA+ 7 OUTB 1000PF C11 IN 100 R12 8 J8 J7 J6 C14 10UF 4 U1 MAX44242AUA+ VSS 1 OUTA VDD IN -6.5V C12 0.1UF U2 MAX44242AUA+ VSS INA+ 1 OUTA INA- VDD C8 R9 INB- INB+ C10 R11 INA- INA+ C6 10UF IN -6.5V PLACE CLOSE TO VDD AND VSS PINS OF U2 +6.5V IN 6 5 2 3 6 5 2 3 +6.5V IN TP8 TP4 TP7 TP6 TP3 TP5 AIN2+ AIN2- AIN1+ AIN1- 0.1% 0.1% R16 IN 1K 0.1% C19 0.1UF 1K IN C18 0.1UF 1K 1K 0.1% REFIN/2 R15 R14 REFIN/2 R13 2 C28 IN 1K IN 1 VOCM SHDN IN+ VOCM IN- OUT+ 1K 1000PF 1000PF 1K IN -6.5V 5 OUTGND C23 R20 0.1% -6.5V 1000PF 1K IN 5 OUTGND +5V 6 6 4 0.1UF 2 3 U4 MAX44205 VS+ VCLPH OUT+ C29 0.1% 0.1% IN IN +6.5V VCLPL VSNC 7 EP 8 11 13 10 1 12 9 R19 C22 C21 R18 VCLPL VSNC 7 EP 8 11 13 10 IN+ 4 0.1UF +5V 0.1% +6.5V 1000PF 3 U3 SHDN MAX44205 VS+ 12 INVCLPH 9 R17 C20 OUT OUT BUFOUT1+ BUFOUT1- C32 0.1UF C34 10UF BUFOUT2- BUFOUT2+ C31 10UF C33 0.1UF C35 10UF C37 0.1UF -6.5V C36 0.1UF IN PLACE CLOSE TO VS+ AND VS- PINS OF U4 +6.5V IN OUT OUT C30 10UF IN -6.5V PLACE CLOSE TO VS+ AND VS- PINS OF U3 +6.5V IN MAX11198 Evaluation Kit Evaluates: MAX11198 MAX11198 EV Kit Schematics Maxim Integrated │  17 BUFOUT2- IN BUFOUT2+ IN BUFOUT1- IN BUFOUT1+ IN R24 R23 R22 R21 0.1% 0.1% 0.1% 0.1% 10 10 10 10 J10 C38 1UF 2 1 C39 0.1UF J11 2 1 C40 0.1UF NR 3 C42 1000PF C41 1000PF 1 IN GND GNDS 2 OUTF OUTS 8 10UF AIN1AIN2+ 3 AIN2- AIN1+ 2 6 12 U5 MAX11192 9 11 0.1UF 13 1 4 C46 C47 1 14 0.1UF J12 1 15 10UF 2 1 C43 4 1.0UF C45 C44 R25 20 DNI +5V IN 5 7 6 AVDD REFGND I.C. I.C. 16 17 10 7 8 DOUT1 DOUT2 10UF 0.1UF C49 2 C48 5 J13 2 SCLK J14 CNVST VREF REF1 REFIN/OUT OGND +5V IN OUT REF2 U14 MAX6126A41 OVDD EP www.maximintegrated.com AGND OUT DOUT2_ADC DOUT1_ADC SCLK_ADC IN OUT CNVST_ADC 10UF C51 IN 0.1UF 0.1UF C53 C50 10UF C52 20 DNI R27 20 DNI R26 +6.5V 2 INA- INA+ 3 1 TP11 0.1UF C55 2 VSS R104 J15 0 1UF C54 OUT IN R29 10K 0.1% R28 10K 0.1% U8_VCC VADJ TP13 TP12 EXT_OVDD 5 U15 MAX44244AUK+ VDD 1 OUTA TP10 REF2 TP9 REF1 4 3 IN C56 0.1UF OUT REFIN/2 MAX11198 Evaluation Kit Evaluates: MAX11198 MAX11198 EV Kit Schematics (continued) Maxim Integrated │  18 VADJ IN +5V IN PD_DAC IN TC/SB_DAC IN RST_DAC IN DIN_DAC IN SCLK_DAC IN CS_DAC IN LDAC IN VREF IN 10K 10K 10K 10K 10K R31 R32 R33 R34 1.0UF R30 C58 C59 1.0UF C57 10UF C60 1.0UF DNI IN IN IN IN IN 20 9 8 1 23 5 6 7 3 16 BYPASS PD TC/SB M/Z RST DIN SCLK CS PD_DAC TC/SB_DAC RST_DAC CS_DAC LDAC 22 LDAC REF C63 0.01UF D1 3.3V C62 0.01UF C61 0.1UF VDDIO 19 12 A 21 11 17 18 10 DGND AVDD2 AGND_S C B0530WS-7-F AGND VADJ IN C A AVDD1 D2 AGND_F VREF IN C64 0.01UF OUT BUSY RFB READY DOUT REF0 25 13 2 14 24 4 15 U6 MAX5316GTG+ EP www.maximintegrated.com AVSS +5V IN C66 C67 10UF R36 49.9 2.1K 100PF R35 C65 0.1UF 10K R37 BUSY_DAC C68 0.01UF OUT VADJ READY_DAC OUT IN DOUT_DAC OUT VREF IN R38 0.1% 10K R39 C69 10K -6.5V IN 3 2 +6.5V IN 0.1% 1000PF INA+ INA- 4 0.1UF 1.0UF C71 C70 1 1.0UF 0.1UF U7 MAX44242AUA+ VDD OUTA VSS 8 C73 C72 5 INB+ 6 INB- OUTB 7 U7 MAX44242AUA+ OUT DAC_OUT_BUFF MAX11198 Evaluation Kit Evaluates: MAX11198 MAX11198 EV Kit Schematics (continued) Maxim Integrated │  19 C75 1UF C74 1UF 3V3_FPGA +12V_FPGA 3V3_FPGA OUT 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 D5 D6 D7 D8 D9 D10 D11 D12 D13 D14 D15 D16 D17 D18 D19 D20 D21 D22 D23 D24 D25 D26 30 31 29 30 31 32 33 34 35 36 37 38 39 40 D30 D31 D32 D33 D34 D35 D36 D37 D38 D39 D40 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 35 36 37 38 39 40 C1 C2 C3 C4 C5 C6 C7 C8 C9 C10 C11 C12 C13 C14 C15 C16 C17 C18 C19 C20 C21 C22 C23 C24 C25 C26 C27 C28 C29 C30 C31 C32 C33 C34 C35 C36 C37 C38 C39 C40 CON1 ASP-134604-01 28 28 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 H40 H39 H38 H37 H36 H35 H34 H33 H32 H31 H30 H29 H28 H27 H26 H25 H24 H23 H22 H21 H20 H19 H18 H17 H16 H15 H14 H13 H12 H11 H10 H9 H8 H7 H6 H5 H4 H3 H2 H1 G40 G39 G38 G37 G36 G35 G34 G33 G32 G31 G30 G29 G28 G27 G26 G25 G24 G23 G22 G21 G20 G19 G18 G17 G16 G15 G14 G13 G12 G11 G10 G9 G8 G7 G6 G5 G4 G3 G2 G1 CON1 ASP-134604-01 40 39 38 37 36 35 34 33 32 29 27 27 D28 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 D29 D27 26 4 D4 3 2 3 D3 1 2 D2 CON1 ASP-134604-01 1 CON1 ASP-134604-01 D1 VADJ C76 1UF R45 R44 R43 R42 R41 R40 VADJ R65 R64 R63 R62 R61 R60 R59 R58 R57 R56 R55 R54 R53 R52 R51 R50 R49 R48 R47 R46 28 28 28 28 28 28 28 28 28 28 28 28 28 28 28 28 28 28 28 28 28 28 28 28 28 28 SYNC_CLK_OUT OUT DOUT2_ADC_BUFF READY_DAC IN IN OUT OUT OUT DOUT_DAC DIN_DAC CS_DAC SCLK_ADC SCLK_DAC OUT TC/SB_DAC OUT LDAC OUT BUSY_DAC OUT RST_DAC OUT IN DOUT1_ADC_BUFF IN SCLK_ADC_BUFF IN OUT DIN_ADC OUT CNVST_ADC OUT PD_DAC SYNC_CLK_IN IN IN 5 4 3 2 SYNC_CLK_OUT IN 1 J16 SYNC_CLK_IN SO_EEPROM_FPGA 5 4 3 2 www.maximintegrated.com TP14 49.9 R66 SYNC_CLK_OUT 1 0 R67 C77 1UF 1 2 3 4 5 6 1A 2OE 2 7 GND 4 2Y 1Y 2OE 2A 5 1A 7 1OE 1 2 GND 4 U17 74LVC2G125DP 8 VCC 2Y 1Y 3V3_FPGA 2A 1OE 1 U16 74LVC2G125DP 8 VCC 5 J18 DO 1 3 6 C80 1000PF 3 6 C79 1000PF PBC06SAAN DNI DI VSS 2 49.9 R69 0 R68 1 1 5 IN 4 3 OUT J19 SYNC_CLK_OUT TP15 SYNC_CLK_IN SO_EEPROM_FPGA C82 0.1UF C81 0.1UF OUT U18 6 93LC66BT-I/OT VCC CLK CS 3V3_FPGA 3 4 5 C78 0.1UF 3V3_FPGA SCLK_ADC DOUT2_ADC IN DOUT1_ADC IN 2 3 4 5 2A 2OE 3A 3OE 4A 5 4 9 10 12 2 GND TP16 SYNC_CLK_IN 4OE 1OE 1 13 1A IN 2 U8_VCC 7 GND VCC 14 C84 0.1UF 4Y 3Y 2Y 1Y 11 8 6 3 U8 74LVC125APW J17 OUT OUT OUT C85 1UF 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 CNVST_ADC DIN_ADC DOUT1_ADC_BUFF DOUT2_ADC_BUFF SCLK_ADC SCLK_ADC_BUFF TC/SB_DAC LDAC BUSY_DAC CS_DAC SCLK_DAC DIN_DAC DOUT_DAC SCLK_ADC_BUFF DOUT2_ADC_BUFF DOUT1_ADC_BUFF MAX11198 Evaluation Kit Evaluates: MAX11198 MAX11198 EV Kit Schematics (continued) Maxim Integrated │  20 GND J20 KLDX-0202-B TP17 3 2 3 2 1 1 EXT_+12V 1 2 C MBR0520L D3 EXT_+12V IN +12V_FPGA IN A J22 1 2 3 1 2 C100 22UF J23 1 + C101 22UF R95 191K R94 191K 2 1 + 2 C105 DNI C103 1UF C104 DNI C102 1UF 8 4 3 2 1 8 4 3 2 1 EP 11 RESET FB VOUT GND LX MODE SS EP 11 RT/SYNC EN/UVLO IN RESET FB VOUT GND LX U13 MAX17552ATB+ MODE SS RT/SYNC EN/UVLO IN U12 MAX17552ATB+ 7 5 6 9 7 5 6 9 10 10 1 1 L2 220UH L1 220UH 2 2 C109 10UF C108 1000PF C107 10UF C106 1000PF R99 49.9K R98 357K R97 49.9K R96 357K 1 TP19 J25 TP18 J24 R101 100K R100 100K 1 2 2 1 2 L4 33UH 2 2 2 XPL2010-333ML L6 33UH C112 4.7UF XPL2010-333ML L5 33UH TP21 -6.5V TP20 TP23 C113 4.7UF XPL2010-333ML C110 4.7UF 1 1 L3 33UH XPL2010-333ML C111 4.7UF 1 TP22 +6.5V A K TERM_BLK OUT R103 10K +6.5V OUT C115 0.1UF DS2 GREEN C114 1UF DS1 GREEN R102 10K A www.maximintegrated.com K J21 -6.5V 2 1 OUT IN GND EP NC 3 OUT IN U20 MAX15006BATT+ 7 6 5 4 C116 10UF +5V 50MA TP24 TP25 GND OUT +5V MAX11198 Evaluation Kit Evaluates: MAX11198 MAX11198 EV Kit Schematics (continued) Maxim Integrated │  21 MAX11198 Evaluation Kit Evaluates: MAX11198 MAX11198 EV Kit PCB Layout Diagrams MAX11198 EV Kit—Top Silkscreen MAX11198 EV Kit—Top Paste MAX11198 EV Kit—Top Mask MAX11198 EV Kit—Top www.maximintegrated.com Maxim Integrated │  22 MAX11198 Evaluation Kit Evaluates: MAX11198 MAX11198 EV Kit PCB Layout Diagrams (continued) MAX11198 EV Kit—Internal 2 MAX11198 EV Kit—Internal 3 MAX11198 EV Kit—Internal 4 MAX11198 EV Kit—Internal 5 www.maximintegrated.com Maxim Integrated │  23 MAX11198 Evaluation Kit Evaluates: MAX11198 MAX11198 EV Kit PCB Layout Diagrams (continued) MAX11198 EV Kit—Bottom Silkscreen MAX11198 EV Kit—Bottom Paste MAX11198 EV Kit—Bottom Mask MAX11198 EV Kit—Bottom www.maximintegrated.com Maxim Integrated │  24 MAX11198 Evaluation Kit Evaluates: MAX11198 Ordering Information PART TYPE MAX11198EVKIT# EVKIT #Denotes RoHS compliant. Contact Avnet to purchase a ZedBoard (AES-Z7EV-7Z020-G) to communicate with the MAX11198 EV kit. www.maximintegrated.com Maxim Integrated │  25 MAX11198 Evaluation Kit Evaluates: MAX11198 Revision History REVISION NUMBER REVISION DATE 0 10/17 DESCRIPTION Initial release PAGES CHANGED — For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642, or visit Maxim Integrated’s website at www.maximintegrated.com. Maxim Integrated cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim Integrated product. No circuit patent licenses are implied. Maxim Integrated reserves the right to change the circuitry and specifications without notice at any time. Maxim Integrated and the Maxim Integrated logo are trademarks of Maxim Integrated Products, Inc. © 2017 Maxim Integrated Products, Inc. │  26