MAX5110EVKIT+

MAX5110 Evaluation Kit General Description The MAX5110 evaluation kit (EV kit) provides a proven design to evaluate the MAX5110 9-channel, 14-bit current DAC. The EV kit also includes Windows XP®-, Windows Vista®-, and Windows® 7-compatible software that provides a simple graphical user interface (GUI) for exercising the features of the device. The EV kit comes with a MAX5110GTJ+ installed. Contact the factory for free samples of the pin-compatible MAX5111GTJ+ to evaluate this device. Evaluates: MAX5110/MAX5111 Features ●● On-Board +3.0V Regulator Accepts +5.5V to +3.35V Supply Range ●● On-Board -5.2V Regulator Accepts -6.5V to -5.24V Supply Range ●● Windows XP-, Windows Vista-, and Windows 7-Compatible Software ●● USB-PC Connection (Cable Included) ●● On-Board Diode and Resistive Loads ●● SPI™ Interface Terminals (MAX5110) ●● I2C Interface Terminals (MAX5111) ●● Proven PCB Layout ●● Fully Assembled and Tested Ordering Information TYPE EV Kit +Denotes lead(Pb)-free and RoHS compliant. Component List DESIGNATION QTY C10–C18, C100–C104, C111, C121, C122 17 0.1µF ±10%, 25V X7R ceramic capacitors (0603) TDK C1608X7R1E104K C21, C22, C31, C32, C108, C131, C141 7 1µF ±10%, 16V X7R ceramic capacitors (0603) TDK C1608X7R1C105K C23, C109, C132, C142 4 10µF ±10%, 6.3V X7R ceramic capacitors (0805) Murata GRM21BR70J106K C33 0 Not installed, ceramic capacitor (0805) C105 1 0.01µF ±10%, 16V X7R ceramic capacitor (0402) Murata GRM155R71C103K C106, C107 2 22pF ±5%, 50V C0G ceramic capacitors (0603) Murata GRM1885C1H220J DESCRIPTION Windows, Windows XP, and Windows Vista are registered trademarks of Microsoft Corp. SPI is a trademark of Motorola, Inc. 19-5600; Rev 0; 10/10 PART MAX5110EVKIT+ DESIGNATION QTY DESCRIPTION C110 1 33000pF ±10%, 25V X7R ceramic capacitor (0603) Murata GRM188R71E333K C123, C124 2 10pF ±5%, 50V C0G ceramic capacitors (0603) Murata GRM1885C1H100J D11A–D14A, D11B– D14B, D11C–D14C, D11D–D14D, D21A– D24A, D21B–D24B, D21C–D24C, D21D– D24D, D31, D32, D34, D35, D36, D41, D42, D43, D51, D52, D61, D62, D71, D72, D73, D81–D85, D91–D95 57 200mA, 25V Schottky diodes (SOT23) Fairchild BAT54 D33 1 1N4001 diode Diodes Inc. 1N4001 D44, D53, D74 3 1N4148 diodes (SOT23) Fairchild MMBD4148 (Top Mark: 5H) Evaluates: MAX5110/MAX5111 MAX5110 Evaluation Kit Component List (continued) DESIGNATION QTY H1 1 36-pin (2 x 18) header DESCRIPTION DESIGNATION QTY R101, R102 2 27Ω ±5% resistors (0603) DESCRIPTION H2 1 8-pin header R103 1 1.5kΩ ±5% resistor (0603) H120, H123 0 Not installed, 9-pin headers R104 1 470Ω ±5% resistor (0603) HOUT1A–HOUT1D, HOUT2A–HOUT2D, HOUT3–HOUT9 R111 1 2.2kΩ ±5% resistor (0603) 15 2-pin headers R112 1 10kΩ ±5% resistor (0603) 200Ω ±5% resistors (0603) 0 Not installed, 10-pin (2 x 5) header 8 JTAGU120 RL1A–RL1D, RL2A–RL2D RL4, RL7 2 22Ω ±5% resistors (1206) JU10, JU11, JU16, JU17 4 2-pin headers JU12, JU13, JUOUT1A– JUOUT1D, JUOUT2A– JUOUT2D, JUOUT4, JUOUT5, JUOUT7, JUOUT8, JUOUT9 RL5 1 11Ω ±1%, 0.5W resistor (1210) KOA Speer RK73H2ETTD11R0F 15 JU14, JU15, JUOUT6 3-pin headers RL31 1 100Ω ±5% resistor (0603) RL81, RL82, RL91, RL92 4 270Ω ±5% resistors (0603) RLEDPWR 1 330Ω ±5% resistor (0603) TP0 1 Black multipurpose test point 3 4-pin headers JU101–JU108 0 Not installed, headers— shorted with PCB trace TP1, TP22 2 Red multipurpose test points JUOUT3 1 5-pin header TP2, TP32 2 L101 1 Ferrite bead (0603) TDK MMZ1608R301A Yellow multipurpose test points LEDPWR 1 Red LED (0805) TP00, TP10, TP100, TP101, TP108, TP132, TP142 0 Not installed, multipurpose test points Q100 1 p-channel FET (SOT223) Fairchild Semi NDT456P R11 1 1MΩ ±5% resistor (0603) U1 1 R16, R17 2 4.7kΩ ±5% resistors (0603) 9-channel, 14-bit current DAC (32 TQFN-EP*) Maxim MAX5110GTJ+ R21 1 220kΩ ±1% resistor (0603) R22 1 80.6kΩ ±1% resistor (0603) U2 1 R31 1 316kΩ ±1% resistor (0603) 3.3V at 1000mA LDO regulator (16 TSSOP-EP*) Maxim MAX8869EUE33+ R32 1 100kΩ ±1% resistor (0603) R41, R42, R43, R51, R52, R71, R72, R73 8 10Ω ±5% resistors (0603) U3 1 -5V at 200mA LDO regulator (5 SOT23) Maxim MAX1735EUK30+ (Top Mark: ADOY) 2 6.8Ω ±5%, 1W resistors (2512) Vishay/Dale CRCW25126R80JNEG U100 1 UART-to-USB converter (32 TQFP) U110 0 Not installed, 93C46-type 3-wire EEPROM 16-bit architecture (8 SO) R61, RL61 R62, RL62 2 33Ω ±5% resistors (0805) R100, RL32 2 1kΩ ±5% resistors (0603) www.maximintegrated.com Maxim Integrated │  2 Evaluates: MAX5110/MAX5111 MAX5110 Evaluation Kit Component List (continued) DESIGNATION QTY DESCRIPTION U120 1 Low-power microcontroller (68 QFN-EP*) Maxim MAXQ2000-RAX+ U130 1 2.5V regulator (5 SC70) Maxim MAX8511EXK25+T (Top Mark: ADV) U140 1 3.3V regulator (5 SC70) Maxim MAX8511EXK33+T (Top Mark: AEI) 1 USB type-B right-angle female receptacle USB1 DESIGNATION QTY DESCRIPTION Y100 1 6MHz crystal Hong Kong X’tals SSL60000N1HK188F0-0 Y120 1 16MHz crystal Hong Kong X’tals SSM16000N1HK188F0-0 — 1 USB high-speed A-to-B cables, 6ft — 23 Shunts — 1 PCB: MAX5110 EVALUATION KIT+ *EP = Exposed pad. Component Suppliers SUPPLIER PHONE WEBSITE Diodes Incorporated Fairchild Semiconductor 805-446-4800 888-522-5372 www.diodes.com www.fairchildsemi.com Hong Kong X’tals Ltd. Murata Electronics North America, Inc. 852-35112388 770-436-1300 www.hongkongcrystal.com www.murata-northamerica.com TDK Corp. Vishay 847-803-6100 402-563-6866 www.component.tdk.com www.vishay.com Note: Indicate that you are using the MAX5110 when contacting these component suppliers. MAX5110 EV Kit Files FILE DESCRIPTION INSTALL.EXE Installs the EV kit files on your computer MAX5110.EXE Application program CDM20600.EXE Installs the USB device driver UNINSTALL.EXE Uninstalls the EV kit software USB_Driver_Help_200.PDF Uninstalls the EV kit software www.maximintegrated.com Maxim Integrated │  3 MAX5110 Evaluation Kit Quick Start Required Equipment ● MAX5110 EV kit (USB cable included) ● Windows XP, Windows Vista, or Windows 7 PC with a spare USB port ● User-supplied +5V DC at 750mA power supply ● User-supplied -5.5V DC at 100mA power supply ● Digital voltmeters (DVMs) Note: In the following sections, software-related items are identified by bolding. Text in bold refers to items directly from the EV kit software. Text in bold and underlined 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, 5110Rxx.ZIP. Save the EV kit software to a temporary folder and uncompress the ZIP file. 2) Install the EV kit software and USB driver on your computer by running the INSTALL.EXE program inside the temporary folder. The program files are copied to your PC and icons are created in the Windows Start | Programs menu. During software installation, some versions of Windows may show a warning message indicating that this software is from an unknown publisher. This is not an error condition and it is safe to proceed with installation. Administrator privileges are required to install the USB device driver on Windows. 3) Verify that all jumpers (JU10–JU17, JUOUT1A– JUOUT2D, JUOUT3–JUOUT9) are in their default positions, as shown in Tables 1 and 2. 4) To measure OP9, connect the DVM between HOUT9 (OP9) and GND (optionally, outputs can be monitored at the labeled test points on header H1). 5) Connect the +5V DC power supply between TP1 (+5V) and TP0 (GND). 6) Connect the -5.5V DC power supply between TP2 (-5.5V) and TP0 (GND). www.maximintegrated.com Evaluates: MAX5110/MAX5111 7) Enable both power supplies. 8) Connect the USB cable from the PC to the EV kit board. A Windows message appears when connecting the EV kit board to the PC for the first time. Each version of Windows has a slightly different message. If you see a Windows message stating ready to use, then proceed to the next step. Otherwise, open the USB_Driver_Help_200.PDF document in the Windows Start | Programs menu to verify that the USB driver was installed successfully. 9) Start the EV kit software by opening its icon in the Windows Start | Programs menu. The EV kit software main window appears, as shown in Figure 1. DAC1 Output MUX Test 1) Press F1 to return to the block diagram. Click on OP1 to drill down to IDAC Configuration for OP1. 2) Connect a DVM to HOUT1A. 3) Under the Output pin to drive drop-down list, select OP1A. 4) Drag the Source Mode Code track bar to the right. 5) Verify that the DVM connected to HOUT1A shows approximately +2.0V (10mA output current). 6) Connect a DVM to HOUT1B. 7) Verify that the DVM connected to HOUT1B shows approximately 0V (0mA output current). 8) Under the Output pin to drive drop-down list, select OP1B. 9) Verify that the DVM connected to HOUT1B shows approximately +2.0V (10mA output current). 10) Connect a DVM to HOUT1C. 11) Verify that the DVM connected to HOUT1C shows approximately 0V (0mA output current). 12) Under the Output pin to drive drop-down list, select OP1C. 13) Verify that the DVM connected to HOUT1C shows approximately +2.0V (10mA output current). 14) Connect a DVM to HOUT1D. 15) Verify that the DVM connected to HOUT1D shows approximately 0V (0mA output current). Maxim Integrated │  4 MAX5110 Evaluation Kit Evaluates: MAX5110/MAX5111 16) Under the Output pin to drive drop-down list, select OP1D. 3) Verify that the DVM connected to HOUT3 shows approximately 0V (0mA output current). 17) Verify that the DVM connected to HOUT1D shows approximately +2.0V (10mA output current). 4) Click on the High current range radio button. DAC2 Output MUX Test 6) Verify that the DVM connected to HOUT3 shows approximately +2.0V (20mA output current). 1) Under the IDAC to configure drop-down list, select OP2. 2) Connect a DVM to HOUT2A. 3) Under the Output pin to drive drop-down list, select OP2A. 4) Drag the Source Mode Code track bar to the right. 5) Verify that the DVM connected to HOUT2A shows approximately +2.0V (10mA output current). 6) Connect a DVM to HOUT2B. 7) Verify that the DVM connected to HOUT2B shows approximately 0V (0mA output current). 8) Under the Output pin to drive drop-down list, select OP2B. 9) Verify that the DVM connected to HOUT2B shows approximately +2.0V (10mA output current). 10) Connect a DVM to HOUT2C. 11) Verify that the DVM connected to HOUT2C shows approximately 0V (0mA output current). 12) Under the Output pin to drive drop-down list, select OP2C. 13) Verify that the DVM connected to HOUT2C shows approximately +2.0V (10mA output current). 14) Connect a DVM to HOUT2D. 15) Verify that the DVM connected to HOUT2D shows approximately 0V (0mA output current). 16) Under the Output pin to drive drop-down list, select OP2D. 17) Verify that the DVM connected to HOUT2D shows approximately +2.0V (10mA output current). 5) Drag the Source Mode Code track bar to the right. 7) Click on the Low current range radio button. 8) Verify that the DVM connected to HOUT3 shows approximately +0.2V (2mA output current). DAC4 Current-Source Test 1) Click on OP4 to drill down to IDAC Configuration for OP4. 2) Connect a DVM to HOUT4. 3) Drag the Source Mode Code track bar to the right. 4) Verify that the DVM connected to HOUT4 shows approximately +2.0V (90mA output current). DAC5 Current-Source Test 1) Click on OP5 to drill down to IDAC Configuration for OP5. 2) Connect a DVM to HOUT5. 3) Drag the Source Mode Code track bar to the right. 4) Verify that the DVM connected to HOUT5 shows approximately +2.0V (180mA output current). DAC6 Source-Mode Test 1) Press F1 to return to the block diagram. Click on OP6 to drill down to IDAC Configuration for OP6. 2) Connect a DVM to HOUT6. 3) Drag the Source Mode Code track bar to the right. 4) Verify that the DVM connected to HOUT6 shows approximately +2.0V (300mA output current). DAC6 Sink-Mode Test 1) Press F1 to return to the block diagram. Click on OP6 to drill down to IDAC Configuration for OP6. DAC3 Range Test 2) Connect a DVM to HOUT6. 1) Press F1 to return to the block diagram. Click on OP3 to drill down to IDAC Configuration for OP3. 3) Drag the Sink Mode Code track bar to the right. 2) Connect a DVM to HOUT3. 5) Verify that the DVM connected to HOUT6 shows approximately -0.4V (-60mA output current). www.maximintegrated.com 4) Click on the Low current range radio button. Maxim Integrated │  5 MAX5110 Evaluation Kit Evaluates: MAX5110/MAX5111 DAC6 Shutter-Mode Test DAC9 Current-Source Test 1) Press F1 to return to the block diagram. Click on OP6 to drill down to IDAC Configuration for OP6. 1) Click on OP9 to drill down to IDAC Configuration for OP9. 2) Connect a DVM to HOUT6. 2) Connect a DVM to HOUT9. 3) Drag the Shutter Mode Code track bar to the center. 3) Drag the Source Mode Code track bar to the right. 4) Click on the High current range radio button. 4) Verify that the DVM connected to HOUT9 shows approximately +2.0V (15mA output current). 5) Under CLR pin action, click on the SHUTTER radio button. 6) Set CLR pin to High to enter shutter mode. 7) Verify that the DVM connected to HOUT6 shows approximately -0.2V (-30mA output current). 8) Set CLR pin to Low to exit shutter mode. 9) Verify that the DVM connected to HOUT6 shows approximately +2.0V (300mA output current). DAC7 Current-Source Test 1) Click on OP7 to drill down to IDAC Configuration for OP7. 2) Connect a DVM to HOUT7. 3) Drag the Source Mode Code track bar to the right. 4) Verify that the DVM connected to HOUT7 shows approximately +2.0V (90mA output current). DAC8 Current-Source Test 1) Click on OP8 to drill down to IDAC Configuration for OP8. 2) Connect a DVM to HOUT8. 3) Drag the Source Mode Code track bar to the right. Detailed Description of Software The main window of the evaluation software (Figure 1) displays the output code for all DAC outputs. In addition, the main window has four tabs. The Block Diagram tab sheet shows the status of all nine DACs. Click on a DAC to drill down to the IDAC Configuration tab sheet (Figure 2). The Registers tab sheet (Figure 3) provides low-level access to all device registers. The Interface History tab sheet (Figure 4) shows the sequence of I2C or SPI operations that have been performed. Advanced User Interface There are two methods for communicating with the device. The first is through the windows shown in Figures 1–4. The second is through the Advanced User Interface window shown in Figures 5 and 6. The Advanced User Interface window becomes available by selecting the Option | Interface (Advanced User) menu item and allows execution of serial commands manually. The Advanced User Interface window can also be used as a debug tool because it is capable of manually reading and writing to every register of the device. 4) Verify that the DVM connected to HOUT8 shows approximately +2.0V (15mA output current). www.maximintegrated.com Maxim Integrated │  6 MAX5110 Evaluation Kit Evaluates: MAX5110/MAX5111 Figure 1. MAX5110 EV Kit Software Main Window (Block Diagram Tab) www.maximintegrated.com Maxim Integrated │  7 MAX5110 Evaluation Kit Evaluates: MAX5110/MAX5111 Figure 2. MAX5110 EV Kit Software Main Window (IDAC Configuration Tab) www.maximintegrated.com Maxim Integrated │  8 MAX5110 Evaluation Kit Evaluates: MAX5110/MAX5111 Figure 3. MAX5110 EV Kit Software Main Window (Registers Tab) www.maximintegrated.com Maxim Integrated │  9 MAX5110 Evaluation Kit Evaluates: MAX5110/MAX5111 Figure 4. MAX5110 EV Kit Software Main Window (Interface History Tab) www.maximintegrated.com Maxim Integrated │  10 MAX5110 Evaluation Kit Evaluates: MAX5110/MAX5111 Figure 5. Advanced User Interface Window (3-Wire Interface Tab) Figure 6. Advanced User Interface Window (2-Wire Interface Tab) www.maximintegrated.com Maxim Integrated │  11 Evaluates: MAX5110/MAX5111 MAX5110 Evaluation Kit Detailed Description of Hardware The MAX5110 EV kit provides a proven layout for the MAX5110 in a 32-pin TQFN package with an exposed pad. I2C and SPI interface pads and easy-to-use USBPC connection are included on the EV kit. Standard MINIQUSB-equivalent microcontroller circuits (U100–U140) connect from the USB to the SPI and I2C interfaces. The MINIQUSB circuit powers its +2.5V and +3.3V supplies from the +5V USB. External user-supplied power connects to the device through test points TP0, TP1, and TP2. The MAX8869 LDO linear regulator (U2) supplies +3V at 1000mA powered from the external TP1 positive supply. The MAX1735 negative LDO linear regulator (U3) supplies -5.2V at 200mA powered from the external TP2 negative supply. TP0 is the ground return. Jumpers JU10–JU17 connect the MINIQUSB SPI bus, I2C bus, and GPIO signal to the CLR pin, as well as the MINIQUSB +3.3V VDDIO power supply. Each of the outputs has its own dedicated 2-pin output header with GND and a jumper-selectable choice of onboard loads, including both resistive loads and diode loads. The resistive loads produce a voltage drop on the order of +2V at full-scale current. The diode loads mimic a typical fiber-optic system. Output 3 has two resistive loads and two diode loads to support both the 2mA and the 20mA ranges. Output 6 has two parallel strings of diodes, one for source load and the other for sink load. Header H1 connects outputs 1–9 with ground returns and power-supply connections for optional external-user hardware connections. If a standard ribbon cable is connected to H1, ground returns are on alternating wires. User-Supplied SPI Interface To use the EV kit with a user-supplied SPI interface, remove the shunts on JU10–JU17. Connect the DIN, SCLK, CS, DOUT, VDD, GND, and CLR signals to the corresponding pads on header H2 on the EV kit board. Evaluating the MAX5111 The MAX5111 is the I2C version of the MAX5110. To evaluate this device, request a free sample of the MAX5111GTJ+ when ordering the EV kit. With power off, replace U1 with the MAX5111. Move JU12 and JU13 shunts to 2-3. Move JU14 and JU15 shunts to 1-2. Move JU16 and JU17 shunts to 1-2 (see Table 1). User-Supplied I2C Interface To evaluate the MAX5111 using the EV kit with a usersupplied I2C interface, remove the shunts from JU10– JU17. Connect the SDA, SCL, A0, A1, VDD, GND, and CLR signals to the corresponding pads on header H2 on the EV kit board. Table 1. Jumper Descriptions (JU10–JU17) JUMPER SIGNAL JU10 VDDI JU11 JU12 CLR DIN/SDA SHUNT POSITION 1-2* JU14 SCLK/SCL CS/A0 www.maximintegrated.com MINIQUSB powers digital interface VDDI with 3.3V from U14. Open User-supplied interface powers VDDI logic supply. 1-2* MINIQUSB drives CLR pin under software control. Open User-supplied interface drives CLR, pulled low (inactive) by R11. 1-2* MINIQUSB SPI interface (master-out/slave-in data). 2-3 MINIQUSB I2C interface (SDA). Open JU13 DESCRIPTION User-supplied interface connected to header H2. 1-2* MINIQUSB SPI interface (clock). 2-3 MINIQUSB I2C interface (SCL). Open User-supplied interface connected to header H2. 1-2 MINIQUSB I2C interface address select A0 = 0. 1-3* MINIQUSB SPI interface (chip select). 1-4 MINIQUSB I2C interface address select A0 = 1. Open User-supplied interface connected to header H2. Maxim Integrated │  12 Evaluates: MAX5110/MAX5111 MAX5110 Evaluation Kit Table 1. Jumper Descriptions (JU10–JU17) (continued) JUMPER JU15 SIGNAL DOUT/A1 JU16 SCL JU17 SDA SHUNT POSITION DESCRIPTION 1-2 MINIQUSB I2C interface address select A1 = 0. 1-3* MINIQUSB SPI interface (master-in/slave-out data). 1-4 MINIQUSB I2C interface address select A1 = 1. Open User-supplied interface connected to header H2. 1-2 Open* 1-2 Open* MINIQUSB I2C SCL pullup resistor R16 is enabled. MINIQUSB SPI does not require pullup R16. MINIQUSB I2C SCL pullup resistor R17 is enabled. MINIQUSB SPI does not require pullup R17. *Default position. Table 2. Load Jumper Descriptions (JUOUT1A–JUOUT9) JUMPER SIGNAL SHUNT POSITION 1-2 Output connects to 10mA diode load. JUOUT1A OUT1A 2-3* Output connects to 10mA resistive load. Open JUOUT1B OUT1B OUT1C 1-2 Output connects to 10mA diode load. Output connects to 10mA resistive load. OUT1D Output connects to 10mA diode load. 2-3* Output connects to 10mA resistive load. OUT2A Output connects to 10mA diode load. 2-3* Output connects to10mA resistive load. OUT2B 1-2 Output connects to10mA diode load. Output connects to 10mA resistive load. OUT2C Output connects to 10mA diode load. 2-3* Output connects to 10mA resistive load. OUT2D Output connects to 10mA diode load. 2-3* Output connects to 10mA resistive load. Output requires user-supplied current load. 1-2 Output connects to 10mA diode load. 2-3* Output connects to 10mA resistive load. Open www.maximintegrated.com Output requires user-supplied current load. 1-2 Open JUOUT2D Output requires user-supplied current load. 1-2 Open JUOUT2C Output requires user-supplied current load. 2-3* Open JUOUT2B Output requires user-supplied current load. 1-2 Open JUOUT2A Output requires user-supplied current load. 1-2 Open JUOUT1D Output requires user-supplied current load. 2-3* Open JUOUT1C DESCRIPTION Output requires user-supplied current load. Maxim Integrated │  13 Evaluates: MAX5110/MAX5111 MAX5110 Evaluation Kit Table 2. Load Jumper Descriptions (JUOUT1A–JUOUT9) (continued) JUMPER JUOUT3 SIGNAL OUT3 SHUNT POSITION 1-2 Output connects to 2mA diode load. 1-3 Output connects to 20mA diode load. 1-4 Output connects to 2mA resistive load. 1-5* Output connects to 20mA resistive load. Open JUOUT4 OUT4 OUT5 Output connects to 90mA diode load. 2-3* Output connects to 90mA resistive load. OUT6 Output connects to 180mA diode load. 2-3* Output connects to 180mA resistive load. OUT7 Output connects to 300mA/-60mA diode load. 1-3 Output connects to -60mA resistive load. 1-4* Output connects to 300mA resistive load. OUT8 Output connects to 90mA diode load. 2-3* Output connects to 90mA resistive load. OUT9 Output requires user-supplied current load. 1-2 Output connects to 15mA diode load. 2-3* Output connects to 15mA resistive load. Open JUOUT9 Output requires user-supplied current load. 1-2 Open JUOUT8 Output requires user-supplied current load. 1-2 Open JUOUT7 Output requires user-supplied current load. 1-2 Open JUOUT6 Output requires user-supplied current load. 1-2 Open JUOUT5 DESCRIPTION Output requires user-supplied current load. 1-2 Output connects to 15mA diode load. 2-3* Output connects to 15mA resistive load. Open Output requires user-supplied current load. *Default position. www.maximintegrated.com Maxim Integrated │  14 MAX5110 Evaluation Kit Evaluates: MAX5110/MAX5111 Figure 7a. MAX5110 EV Kit Schematic (Sheet 1 of 6) www.maximintegrated.com Maxim Integrated │  15 MAX5110 Evaluation Kit Evaluates: MAX5110/MAX5111 Figure 7b. MAX5110 EV Kit Schematic (Sheet 2 of 6) www.maximintegrated.com Maxim Integrated │  16 MAX5110 Evaluation Kit Evaluates: MAX5110/MAX5111 Figure 7c. MAX5110 EV Kit Schematic (Sheet 3 of 6) www.maximintegrated.com Maxim Integrated │  17 MAX5110 Evaluation Kit Evaluates: MAX5110/MAX5111 Figure 7d. MAX5110 EV Kit Schematic (Sheet 4 of 6) www.maximintegrated.com Maxim Integrated │  18 MAX5110 Evaluation Kit Evaluates: MAX5110/MAX5111 Figure 7e. MAX5110 EV Kit Schematic (Sheet 5 of 6) www.maximintegrated.com Maxim Integrated │  19 MAX5110 Evaluation Kit Evaluates: MAX5110/MAX5111 Figure 7f. MAX5110 EV Kit Schematic (Sheet 6 of 6) www.maximintegrated.com Maxim Integrated │  20 MAX5110 Evaluation Kit Evaluates: MAX5110/MAX5111 1.0” Figure 8. MAX5110 EV Kit Component Placement Guide—Component Side 1.0” Figure 9. MAX5110 EV Kit PCB Layout—Component Side www.maximintegrated.com Maxim Integrated │  21 MAX5110 Evaluation Kit Evaluates: MAX5110/MAX5111 1.0” Figure 10. MAX5110 EV Kit PCB Layout—Ground Layer 2 1.0” Figure 11. MAX5110 EV Kit PCB Layout—Power Layer 3 www.maximintegrated.com Maxim Integrated │  22 MAX5110 Evaluation Kit Evaluates: MAX5110/MAX5111 1.0” Figure 12. MAX5110 EV Kit PCB Layout—Solder Side www.maximintegrated.com Maxim Integrated │  23 Evaluates: MAX5110/MAX5111 MAX5110 Evaluation Kit Revision History REVISION NUMBER REVISION DATE 0 10/10 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. © 2010 Maxim Integrated Products, Inc. │  24