19-5509; Rev 0; 9/10 MAX11200/MAX11206/MAX11209/MAX11210/ MAX11213 Evaluation Kits The MAX11200, MAX11206, MAX11209, MAX11210, and MAX11213 evaluation kits (EV kits) consist of one MAX11200, MAX11206, MAX11209, MAX11210, or MAX11213 evaluation board and software. The EV kits are fully assembled and tested circuit boards that evaluate the MAX11200 family of ultra-low-power, highresolution, serial output ADCs. XPM-, VistaM-, The EV kits include Windows Windows and WindowsM 7-compatible software that provides a graphical user interface (GUI) for exercising the features of the MAX11200 family of data converters. The EV kits are connected to a PC through a USB A-to-B cable. Features S Windows XP-, Windows Vista-, and Windows 7-Compatible Software S USB-PC Connection (Cable Included) S USB Powered (No External Power Supply Required) S On-Board Isolated Power Supplies Rejecting Power Line Noise S On-Board Optocouplers Isolating ADC from Other Circuitry S Real-Time Data Acquisition through USB S Proven PCB Layout Selector Guide Ordering Information PROGRAMMABLE GAIN PART TYPE MAX11200EVKIT+ EV Kit 24 N/A MAX11206EVKIT+ EV Kit 20 1–128 MAX11209EVKIT+ EV Kit MAX11209EEE+ 18 1–128 MAX11210EVKIT+ EV Kit MAX11210EEE+ 24 1–16 MAX11213EEE+ 16 1–128 PART RESOLUTION MAX11200EEE+ MAX11206EEE+ MAX11213EVKIT+ EV Kit +Denotes lead(Pb)-free and RoHS compliant. Component List DESIGNATION QTY C1 1 C2 DESIGNATION QTY 10FF Q20%, 6.3V X5R ceramic capacitor (0603) Murata GRM188R60J106M C21, C24, C25, C28 4 1FF Q10%, 16V X7R ceramic capacitors (0603) Murata GRM188R71C105K 1 0.01FF Q10%, 16V X7R ceramic capacitor (0603) Murata GRM188R71C 103K C22, C23, C26, C27 4 18pF Q5%, 50V C0G ceramic capacitors (0603) Murata GRM1885C1H180J C3–C10, C13, C14, C15, C17, C18, C33 14 0.1FF Q10%, 25V X7R ceramic capacitors (0603) Murata GRM188R71E104K C34–C37 0 Not installed, ceramic capacitors (0805) D1–D4 4 30V, 1A Schottky diodes (SOD123) C11, C12 2 D5 1 15V zener diode (DO35) D6 1 Green LED (0603) D7 1 Red LED (0603) FB1 1 120 at 100MHz, 200mA ferrite bead (0603) Murata BLM18RK121SN1 C16, C19, C20, C29–C32 7 DESCRIPTION 1000pF Q10%, 50V X7R ceramic capacitors (0603) Murata GRM188R71H102K 4.7FF Q10%, 10V X5R ceramic capacitors (0805) Murata GRM219R61A475K DESCRIPTION Windows, Windows XP, and Windows Vista are registered trademarks of Microsoft Corp. ________________________________________________________________ Maxim Integrated Products 1 For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642, or visit Maxim’s website at www.maxim-ic.com. Evaluate: MAX11200/11206/11209/11210/11213 General Description Evaluate: MAX11200/11206/11209/11210/11213 MAX11200/MAX11206/MAX11209/MAX11210/ MAX11213 Evaluation Kits Component List (continued) DESIGNATION QTY J1 1 12-position terminal block DESCRIPTION J2 1 BNC PC-mount connector J3 1 USB type-B right-angle receptacle J4 0 Not installed, 10-pin (2 x 5) header JU1 1 4-pin header DESIGNATION QTY DESCRIPTION U4, U5, U6 3 High-speed optocouplers (8 DIP) U7 1 H-bridge driver (8 SO-EP*) Maxim MAX256ASA+ U8 1 Linear regulator (8 SO) Maxim MAX1659ESA+ U9 1 Linear regulator (8 SO) Maxim MAX1658ESA+ U10 1 USB peripheral controller (24 TQFN-EP*) Maxim MAX3420EETG+ U11 1 Microcontroller (68 QFN-EP*) Maxim MAXQ2000-RAX+ U12 1 2.5V LDO regulator (5 SC70) Maxim MAX8511EXK25+ U13 1 Adjustable LDO regulator (6 SOT23) Maxim MAX8880EUT+ Y1 1 2.4576MHz clock oscillator Hong Kong X’tals C4L24576NSMI02601-0 JU2–JU5 4 3-pin headers JU6, JU7, JU10 3 2-pin headers JU8, JU9 2 12-pin (2 x 6) headers R1 1 100I Q5% resistor (0603) R2, R3, R4 3 180I Q5% resistors (0603) R5–R8 4 330I Q5% resistors (0603) R9 1 47kI Q5% resistor (0603) R10, R14 2 360I Q5% resistors (0603) R11, R12 2 33.2I Q1% resistors (0603) R13 1 10kI Q5% resistor (0603) R15 1 10.5kI Q1% resistor (0603) R16 1 6.49kI Q1% resistor (0603) R17 1 100kI Q5% resistor (0603) R18, R19 2 10kI Q1% resistors (0603) R20–R23 4 0I Q5% resistors (0603) Y2 1 T1 1 198FH, 3W, 1:1:2.6:2.6-turn 400kHz transformer HALO Electronics TGM-H281NF 2.048MHz clock oscillator Hong Kong X’tals C4L20480NSMI02601-0 Y3 1 12MHz crystal Hong Kong X’tals SSM12000N1HK188F0-0 1 20MHz crystal Hong Kong X’tals SSM20000NSMI02801-0 TP1, TP3 2 Red multipurpose test points TP2, TP4 2 Black multipurpose test points TP5–TP13 9 Orange miniature test points Y4 U1 1 See the EV Kit-Specific Component List — 1 USB high-speed A-to-B cable — 10 Shunts — 1 PCB: MAX11200/11206/11209/1 1210/11213 EVALUATION KIT+ U2 1 4:1 analog multiplexer (16 TSSOP) Maxim MAX4782EUE+ U3 1 High-precision, low-noise voltage reference (8 FMAXM) Maxim MAX6126A30+ *EP = Exposed pad. µMAX is a registered trademark of Maxim Integrated Products, Inc. 2 _______________________________________________________________________________________ MAX11200/MAX11206/MAX11209/MAX11210/ MAX11213 Evaluation Kits PART DESIGNATION DESCRIPTION MAX11200EVKIT+ 24-bit single-channel ADC (16 QSOP) Maxim MAX11200EEE+ MAX11206EVKIT+ 20-bit single-channel ADC (16 QSOP) Maxim MAX11206EEE+ MAX11209EVKIT+ 18-bit single-channel ADC (16 QSOP) Maxim MAX11209EEE+ U1 MAX11210EVKIT+ 24-bit single-channel ADC (16 QSOP) Maxim MAX11210EEE+ MAX11213EVKIT+ 16-bit single-channel ADC (16 QSOP) Maxim MAX11213EEE+ Component Suppliers SUPPLIER PHONE WEBSITE HALO Electronics, Inc. 650-903-3800 www.haloelectronics.com Hong Kong X’tals Ltd. 852-35112388 www.hongkongcrystal.com Murata Electronics North America, Inc. 770-436-1300 www.murata-northamerica.com Note: Indicate that you are using the MAX11200, MAX11206, MAX11209, MAX11210, or MAX11213 when contacting these component suppliers. MAX11200/MAX11206/MAX11209/MAX11210/MAX11213 EV Kit Files FILE DESCRIPTION INSTALL.EXE Installs the EV kit files on your computer 11200_06_09_10_13.EXE UNINST.INI Application program Uninstalls the EV kit software Quick Start Procedure • MAX11200, MAX11206, MAX11209, MAX11210, or MAX11213 EV kit (USB A-to-B cable included) The EV kits are fully assembled and tested. Follow the steps below to verify board operation before exercising the full features of the MAX11200 family of data converters: • Windows XP, Windows Vista, or Windows 7 PC with a spare USB port 1) Verify that all the jumpers are set in their default positions (see Table 3). • High-precision digital voltmeter (DVM) 2) Visit www.maxim-ic.com/evkitsoftware to download the latest version of the EV kit software, 11200_06_09_10_13Rxx.ZIP. Recommended Equipment Refer to the MAX11200/MAX11210, MAX11203/ MAX11213, MAX11206/MAX11207, and MAX11209/ MAX11211 IC data sheets while using this EV kit for detailed descriptions of the device features. 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. 3) Install the evaluation software on your computer by running the INSTALL.EXE program. The program files are copied and icons are created in the Windows Start | Programs menu. 4) Connect the USB cable from the PC to the EV kit board. _______________________________________________________________________________________ 3 Evaluate: MAX11200/11206/11209/11210/11213 EV Kit-Specific Component List Evaluate: MAX11200/11206/11209/11210/11213 MAX11200/MAX11206/MAX11209/MAX11210/ MAX11213 Evaluation Kits 5) Verify that green LED D6 on the EV kit board illuminates, indicating the isolated power supply is good. 6) Verify that red LED D7 on the EV kit board illuminates, indicating the microcontroller has successfully finished the board self-test. 7) Start the EV kit software by opening its icon in the Windows Start | Programs menu. 8) A Device Select window pops up. Select the device variant installed on the EV kit board and press the OK button (Figure 1). 9) The software automatically configures the device to perform a self-calibration and enables the use of the self-calibration offset and self-calibration gain values when computing the final offset and gaincorrected data value (set the CTRL3 register to 0x18). 10) The EV kit software main window appears (Figure 2). Verify that Hardware: Connected is displayed on the status bar at the bottom of the main window. 11) Press the Start Conversion & Data Logging button. The software switches to the Data Analysis tab (Figure 3), displaying the scope of the sampled data. Figure 1. MAX11200/MAX11206/MAX11209/MAX11210/MAX11213 EV Kit Software (Device Select Window) 4 _______________________________________________________________________________________ MAX11200/MAX11206/MAX11209/MAX11210/ MAX11213 Evaluation Kits Evaluate: MAX11200/11206/11209/11210/11213 Figure 2. MAX11200/MAX11206/MAX11209/MAX11210/MAX11213 EV Kit Software (Main Window) _______________________________________________________________________________________ 5 Evaluate: MAX11200/11206/11209/11210/11213 MAX11200/MAX11206/MAX11209/MAX11210/ MAX11213 Evaluation Kits Figure 3. MAX11200/MAX11206/MAX11209/MAX11210/MAX11213 EV Kit Software (Data Analysis Tab) 6 _______________________________________________________________________________________ MAX11200/MAX11206/MAX11209/MAX11210/ MAX11213 Evaluation Kits The user MUST perform at least one calibration (either self-calibration and/or system calibration) before any measurement. Refer to the MAX11200/MAX11210, MAX11203/MAX11213, MAX11206/MAX11207, and MAX11209/MAX11211 IC data sheets for calibration details. The following calibration procedure details how to use all the calibration registers in a measurement. 1) To perform a self-calibration (both offset and gain): a. This is a conversion with internally shorted inputs, which is done by the internal state machine. No user manual action is required. That is, JU9 and JU8 shunt positions can be anywhere. b. In the CAL1, CAL0 group box, select the 01 – Self Calibration radio button. c. In the IMPD group box, select 0 – Calibration/Conversion radio button. the d. Press the Send button. The device performs a self-calibration. 2) To perform a system calibration, a system offset calibration must be performed first: a. This is a conversion with the inputs held at system zero. For the EV kit, one option is to place the shunt on JU9 across pins 7-8 (AINP = GND) and place the shunt on JU8 across pins 7-8 (AINN = GND). In the case of a user system, the user should apply the target system zero to the AINN and AINP inputs. b. In the CAL1, CAL0 group box, select the 10 – System Offset Calibration radio button. c. In the IMPD group box, select 0 – Calibration/Conversion radio button. the d. In the CTRL3 register row, type 18 in the Write Value edit box to enable SCOC and SCGC registers. Press the Write button. e. Press the Send button. The device performs a system offset calibration with self-calibration registers enabled. 3) The second step of the system calibration is to perform a system gain calibration. The SOC register must be enabled before a system gain calibration is performed. a. This is a conversion with the inputs held at system full-scale reference. For the EV kit, one option is to place the shunt on JU9 across pins 1-2 (AINP = REFP = 3.0V) and place the shunt on JU8 across pins 3-4 (AINN = REFN = GND). In the case of a user system, the user should apply the target system full-scale reference to the AINP and AINN inputs. b. In the CAL1, CAL0 group box, select the 11 – System Gain Calibration radio button. c. In the IMPD group box, select 0 – Calibration/Conversion radio button. the d. In the CTRL3 register row, type 10 in the Write Value edit box to enable the system offset register and the self-calibration registers. Press the Write button. e. Press the Send button. The device performs a system gain calibration. 4) To enable the calibration coefficients: a. In the CTRL3 register row, type 00 in the Write Value edit box. Press the Write button. All the self and system calibration gain and offset values are used in the calculation of the conversion result. 5) Continue to perform a measurement by connecting AINP and AINN to the measurement target. Programmable Gain Register Bits In the CTRL3 register of the MAX11206, MAX11209, MAX11210, and MAX11213 devices, there are 3 digital gain bits that control the input-referred gain. The user can change the gain by typing a new value in the CTRL3 _______________________________________________________________________________________ 7 Evaluate: MAX11200/11206/11209/11210/11213 Calibration Notes Evaluate: MAX11200/11206/11209/11210/11213 MAX11200/MAX11206/MAX11209/MAX11210/ MAX11213 Evaluation Kits Table 1. MAX11206/MAX11209/MAX11213 DGAIN[2:0] Decoding Table 2. MAX11210 DGAIN[2:0] Decoding GAIN DGAIN2 DGAIN1 DGAIN0 GAIN DGAIN2 DGAIN1 DGAIN0 1 0 0 0 1 0 0 0 2 0 0 1 4 0 1 0 2 0 0 1 4 0 1 0 8 0 1 1 8 0 1 1 16 1 0 0 16 1 0 0 16 1 0 1 1 16 1 1 0 16 1 1 1 32 1 0 64 1 1 0 128 1 1 1 register row’s Write Value edit box and pressing the Write button. Decoding of programmable gain bits is listed in Tables 1 and 2. Detailed Description of Software Software Main Window In the top section of the main window, an SPIK command byte can be generated. Select the expected bit values and press the Send button to send the command to the ADC. In the middle section of the main window, SPI register access commands can be generated. On each register row, the register bit names are listed. Press the Read button to read the register value. Type in a new value in the Write Value edit box, and press the Write button to write a new value to the register. Every write operation is automatically followed by a readback operation to verify that the write operation is successful. Press the Read All button to read all the register values. Press the Write All button to write all the new values in the edit boxes to the registers. type in the new values, and press Enter to update these values for conversion-result calculation. In the Number of Samples Requested edit box, type in the number of samples expected. Press the Start Conversion & Data Logging button to start a data-acquisition session. For continuous conversion mode, the user can discard the first 3 samples by checking the Do not log the first 3 samples checkbox. Press the Stop Conversion & Data Logging button to stop the data-acquisition session before the requested number of samples is reached. After a data-acquisition session is complete or stopped by the user, the software displays a popup window (Figure 4) asking if the user wants to save the data to a file. If the user presses the Yes button, the software displays a Save As window (Figure 5) to let the user input the file information for logged data. In the bottom section of the main window, EV kit and device status are displayed. The CLK Selection group box lists the clock input options for the MAX11200 family of data converters. The Conversion Mode group box is a duplicate for the SCYCLE register bit. In the REFP, REFN, AVDD group box, the factory-set AVDD and reference voltages are listed. The user can apply user-supplied AVDD and reference voltages, Figure 4. MAX11200/MAX11206/MAX11209/MAX11210/ MAX11213 EV Kit Software (Save Data Information Popup Window) SPI is a trademark of Motorola, Inc. 8 _______________________________________________________________________________________ MAX11200/MAX11206/MAX11209/MAX11210/ MAX11213 Evaluation Kits Data Analysis Tab The Data Analysis tab sheet (Figure 3) shows the waveform scope of the sampled signal. The user can load previous logged data to view the signal waveform by pressing the Load Log File… button. The user can zoom in and zoom out the scope. The user can also save and print the scope screenshot. The user can select the Y axis of the scope to be the ADC conversion counts or the calculated voltage values. scope. Doing data analysis while data acquisition is in progress can cause data loss because the PC may not have enough processing power for multitasking. Logged Data Figure 6 shows a sample of logged data (*.csv) opened in the Microsoft ExcelM spreadsheet. Figure 7 shows the same file opened in the Microsoft Notepad. Use monospaced fonts (such as Courier or Lucida Console) to open the file for clear alignment. When the device works in fast continuous-conversion mode, avoid frequently moving the mouse over the Excel is a registered trademark of Microsoft Corporation. _______________________________________________________________________________________ 9 Evaluate: MAX11200/11206/11209/11210/11213 Figure 5. MAX11200/MAX11206/MAX11209/MAX11210/MAX11213 EV Kit Software (Save As Window) Evaluate: MAX11200/11206/11209/11210/11213 MAX11200/MAX11206/MAX11209/MAX11210/ MAX11213 Evaluation Kits Figure 6. MAX11200/MAX11206/MAX11209/MAX11210/MAX11213 EV Kit Software (Logged Data Opened in Excel) 10 ������������������������������������������������������������������������������������� MAX11200/MAX11206/MAX11209/MAX11210/ MAX11213 Evaluation Kits Evaluate: MAX11200/11206/11209/11210/11213 Figure 7. MAX11200/MAX11206/MAX11209/MAX11210/MAX11213 EV Kit Software (Logged Data Opened in Notepad) ______________________________________________________________________________________ 11 Evaluate: MAX11200/11206/11209/11210/11213 MAX11200/MAX11206/MAX11209/MAX11210/ MAX11213 Evaluation Kits Detailed Description of Hardware The MAX11200, MAX11206, MAX11209, MAX11210, and MAX11213 EV kits are complete evaluation systems for the MAX11200 family of data converters. The EV kits provide on-board isolated power supplies and optocouplers to reduce noise. The EV kits can do simple real-time data acquisition for the user to evaluate the performance of the devices. See Table 3 for a description of all EV kit jumper configurations. Signal Routing When using an external reference, firmly connect the reference cables on pins 9 and 10 of the J1 connector. The devices in the MAX11200 family are single-channel data converters. Normally, the inputs are applied on pins 11 and 12 of the J1 connector. Using GPIO1, GPIO2, and GPIO3 to control the MAX4782 4-channel multiplexer, 4 channels of signals can be input to the MAX11200 family devices. See Table 4 for GPIO1, GPIO2, and GPIO3 functions. Table 3. Jumper Descriptions (JU1–JU10) JUMPER JU1 JU2 JU3 JU4 JU5 JU6 JU7 JU8 JU9 SHUNT POSITON ADC CLK connected to on-board 2.4576MHz clock 1-3 ADC CLK connected to on-board 2.048MHz clock 1-4 ADC CLK connected to a user-supplied clock 1-2* ADC REFP connected to on-board 3.0V reference 2-3 ADC REFP connected to user-supplied reference EXT_REFP 1-2* ADC REFN connected to isolated GND 2-3 ADC REFN connected to user-supplied reference EXT_REFN 1-2* ADC DVDD connected to on-board 3.3V isolated power supply 2-3 ADC DVDD connected to user-supplied power supply 1-2* ADC AVDD connected to on-board 3.3V isolated power supply 2-3 ADC AVDD connected to user-supplied power supply Open* 1-2 Open* Disable 2.4576MHz clock oscillator (reduce noise) Enable 2.4576MHz clock oscillator Disable 2.048MHz clock oscillator (reduce noise) 1-2 Enable 2.048MHz clock oscillator 1-2* ADC AINN connected to REFP 3-4 ADC AINN connected to REFN 5-6 ADC AINN connected to (REFP+REFN)/2 7-8 ADC AINN connected to isolated GND 9-10 ADC AINN connected to EXT_AINN 11-12 ADC AINN connected to MAX4782, pin Y 1-2* ADC AINP connected to REFP 3-4 ADC AINP connected to REFN 5-6 ADC AINP connected to (REFP+REFN)/2 7-8 ADC AINP connected to isolated GND 9-10 ADC AINP connected to EXT_AINP 11-12 ADC AINP connected to MAX4782, pin X 1-2* JU10 DESCRIPTION 1-2* Open ADC DVDD connected to on-board 3.3V isolated power supply ADC DVDD disconnected from on-board 3.3V isolated power supply (for current measurement) *Default position. 12 ������������������������������������������������������������������������������������� MAX11200/MAX11206/MAX11209/MAX11210/ MAX11213 Evaluation Kits SELECT INPUT ENABLE INPUT (GPIO1) B(GPIO2) A(GPIO3) ON SWITCHES CTRL2 REGISTER WRITE EXAMPLE H Don’t care Don’t care All switches open 0xF1 L L L X-X0 Y-Y0 0xF0 L L H X-X1 Y-Y1 0xF4 L H L X-X2 Y-Y2 0xF2 L H H X-X3 Y-Y3 0xF6 ______________________________________________________________________________________ 13 Evaluate: MAX11200/11206/11209/11210/11213 Table 4. MAX4782 Switch Programming (GPIO1, GPIO2, GPIO3) Evaluate: MAX11200/11206/11209/11210/11213 MAX11200/MAX11206/MAX11209/MAX11210/ MAX11213 Evaluation Kits Figure 8a. MAX11200/MAX11206/MAX11209/MAX11210/MAX11213 EV Kit Schematic (Sheet 1 of 2) 14 ������������������������������������������������������������������������������������� MAX11200/MAX11206/MAX11209/MAX11210/ MAX11213 Evaluation Kits Evaluate: MAX11200/11206/11209/11210/11213 Figure 8b. MAX11200/MAX11206/MAX11209/MAX11210/MAX11213 EV Kit Schematic (Sheet 2 of 2) ______________________________________________________________________________________ 15 Evaluate: MAX11200/11206/11209/11210/11213 MAX11200/MAX11206/MAX11209/MAX11210/ MAX11213 Evaluation Kits 1.0” Figure 9. MAX11200/MAX11206/MAX11209/MAX11210/MAX11213 EV Kit Component Placement Guide—Component Side 1.0” Figure 10. MAX11200/MAX11206/MAX11209/MAX11210/MAX11213 EV Kit PCB Layout—Component Side 16 ������������������������������������������������������������������������������������� MAX11200/MAX11206/MAX11209/MAX11210/ MAX11213 Evaluation Kits Figure 11. MAX11200/MAX11206/MAX11209/MAX11210/MAX11213 EV Kit PCB Layout—Inner Layer 2 1.0” Figure 12. MAX11200/MAX11206/MAX11209/MAX11210/MAX11213 EV Kit PCB Layout—Inner Layer 3 ______________________________________________________________________________________ 17 Evaluate: MAX11200/11206/11209/11210/11213 1.0” Evaluate: MAX11200/11206/11209/11210/11213 MAX11200/MAX11206/MAX11209/MAX11210/ MAX11213 Evaluation Kits 1.0” Figure 13. MAX11200/MAX11206/MAX11209/MAX11210/MAX11213 EV Kit PCB Layout—Solder Side 18 ������������������������������������������������������������������������������������� MAX11200/MAX11206/MAX11209/MAX11210/ MAX11213 Evaluation Kits REVISION NUMBER REVISION DATE 0 9/10 DESCRIPTION Initial release PAGES CHANGED — Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time. Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 © 2010 Maxim Integrated Products 19 Maxim is a registered trademark of Maxim Integrated Products, Inc. Evaluate: MAX11200/11206/11209/11210/11213 Revision History