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MAX24210EVKIT#

MAX24210EVKIT#

  • 厂商:

    MICROSEMI(美高森美)

  • 封装:

    -

  • 描述:

    KIT EVALUATION MAX24210

  • 数据手册
  • 价格&库存
MAX24210EVKIT# 数据手册
Rev: 122012 MAX24000-Series EVKIT Evaluates: MAX24000-Series Clock Products General Description The MAX24000-Series EVKIT is an easy-to-use evaluation kit for the Microsemi MAX24000-Series clock synchronization and clock synthesis ICs. A surfacemounted IC device and careful layout provide maximum signal integrity. On-board crystal, XO and TCXO components are provided for use as the device reference clock. Additionally, the board can accept 3 external input clocks which are accessible via SMB connectors. All device output clocks are available via SMB connectors to allow easy evaluation of the device’s jitter performance. The EVKIT can be configured to have four device GPIO pins connected to LEDs or header pins to provide device status information. Device JTAG I/O signals are also accessible via header pins. Finally, an on-board microcontroller and USB interface provide easy configuration and monitoring of the MAX24000-Series device via a Windows®-based software application. This data sheet is for the revision B evaluation board assembly. Each board assembly revision has its own data sheet. Evaluation Kit Contents ♦ MAX24000-series EVKIT Board ♦ Power Supply ♦ USB Cable ♦ 2 SMB to BNC cables ♦ 5 Oscillator Evaluation Daughter Cards Features ♦ Soldered MAX24000-Series Device for Best Signal Integrity ♦ SMB Connectors For Easy Connectivity ♦ Connectors and Termination for Input Clock Signals ♦ On-Board Crystal, XO and TCXO Components for Use as Reference Clocks ♦ Footprints to Support Both 5x7mm and 3x5mm Oscillators ♦ External Oscillator Testing Support ♦ 4 Software Configurable Device Status LEDs and Header Pins ♦ Easy-to-Read Silkscreen Labels Identify the Signals Associated with All Connectors, Jumpers, and LEDs ♦ Windows®-Based Application Software Provides Easy GUI-Based Configuration and Monitoring of Most Common Device Features and Register Level Access to Entire Device Register Set ♦ Software Support for Creating and Running Configuration Scripts Saves Time During Evaluation and System Design Minimum System Requirements ♦ PC Running Windows® XP or Windows® 7 ♦ Display with 1024x768 Resolution or Higher ♦ Available USB Port Ordering Information PART NUMBER DESCRIPTION MAX24210EVKIT Evaluation Kit for MAX24205 and MAX24210 Evaluation Kit for MAX24305 and MAX24310 Internal EEPROM Evaluation Kit for MAX24405 and MAX24410 Evaluation Kit for MAX24505 and MAX24510 Internal EEPROM Evaluation Kit for MAX24605 and MAX24610 Evaluation Kit for MAX24705 and MAX24710 with Internal EEPROM MAX24310EVKIT MAX24410EVKIT MAX24510EVKIT MAX24610EVKIT MAX24710EVKIT 5- or 10-Output An y-Rate Timing ICs 5- or 10-Output An y-Rate Timing ICs with 5- or 10-Output An y-Rate Clock Multipliers 5- or 10-Output An y-Rate Clock Multipliers with 5- or 10-Output An y-Rate Line Card Timing ICs 5- or 10-Output An y-Rate Line Card Timing ICs 1 MAX24000-SERIES EVALUATION KIT Table of Contents 1. OVERVIEW..........................................................................................................................................4 2. BOARD FLOORPLAN AND CONFIGURATION ...............................................................................4 2.1 POWER SUPPLY CONNECTION ............................................................................................................5 2.2 USB CONNECTION .............................................................................................................................5 2.3 HARDWARE CONFIGURATION SETTINGS .............................................................................................5 2.3.1 2.3.2 2.3.3 2.3.4 2.3.5 Power Supply ............................................................................................................................... 5 Reset and Microprocessor ............................................................................................................ 5 Master Clock Oscillator ................................................................................................................. 5 Input Clock s ................................................................................................................................. 5 Output Clock s .............................................................................................................................. 5 GPIO HEADER AND STATUS LEDS ...................................................................................................10 POWER-UP CONFIGURATION FROM INTERNAL/E XTERNAL EEPROM .................................................10 JTAG HEADER .................................................................................................................................10 3. SOFTWARE INSTALLATION ..........................................................................................................11 3.1 SOFTWARE APPLIC ATION INSTALLATION ...........................................................................................11 3.2 USB VIRTUAL COM PORT DEVICE DRIVER INSTALLATION ................................................................11 3.3 COMMAND LINE OPTIONS .................................................................................................................12 4. SOFTWARE APPLICATION OVERVIEW........................................................................................12 2.4 2.5 2.6 4.1 4.2 4.3 4.4 4.5 4.6 4.7 4.8 4.9 4.10 4.11 MAIN MENU ......................................................................................................................................12 APLL CONFIGURATION MENU ..........................................................................................................17 OUTPUT CLOCK CONFIGURATION MENU ...........................................................................................18 DPLL MASTER CLOCK CONFIGURATION MENU .................................................................................19 DPLL CONFIGURATION MENU ..........................................................................................................20 DPLL INPUT CLOCK CONFIGUR ATION MENU.....................................................................................21 POWER METER MENU ......................................................................................................................22 I/O PIN CONFIGURATION MENU ........................................................................................................24 EEPROM MENU ..............................................................................................................................25 REGISTER VIEW MENU..................................................................................................................26 CONFIGURATION SCRIPTS AND LOG FILES ....................................................................................27 4.11.1 4.11.2 Configuration Log File................................................................................................................. 27 Configuration Scripts .................................................................................................................. 27 5. EVKIT ERRATA ................................................................................................................................30 6. REVISION HISTORY.........................................................................................................................30 7. BILL OF MATERIALS.......................................................................................................................31 8. SCHEMATICS ...................................................................................................................................34 2 MAX24000-SERIES EVALUATION KIT List of Figures Figure 1. MA X24000-series EVKIT Rev B Board Floorplan.................................................................................. 4 Figure 2. EVKIT Software Main Menu - MA X24310 Rev A1 ............................................................................... 12 Figure 3. Input Clock Frequency Calculator Menu............................................................................................. 13 Figure 4. APLL1 Output Frequency Calculator Menu ........................................................................................ 14 Figure 5. APLL1 Configuration Menu ............................................................................................................... 17 Figure 6. Output Clock Configuration Menu ...................................................................................................... 18 Figure 7. DPLL Master Clock Configuration Menu............................................................................................. 19 Figure 8. DPLL Configuration Menu ................................................................................................................. 20 Figure 9. DPLL Input Clock Configuration Menu ............................................................................................... 21 Figure 10. Power Meter Menu, Estimated Mode ............................................................................................... 22 Figure 11. Power Meter Menu, Measured Mode ............................................................................................... 23 Figure 12. I/ O Pin Configuration Menu ............................................................................................................. 24 Figure 13. EEPROM Menu.............................................................................................................................. 25 Figure 14. Register View Menu........................................................................................................................ 26 Figure 14. EVKIT Bill of Materials .................................................................................................................... 31 Figure 14. EVKIT 50MHz Crystal Daughter Card Bill of Materials ....................................................................... 34 Figure 14. EVKIT 49.152MHz Crystal Daught er Card Bill of Materials ................................................................ 34 List of Tables Table 1. Table 2. Table 3. Table 4. Table 5. Table 6. Table 7. Table 8. Power Supply Hardware Configuration.................................................................................................. 6 Reset and Microprocessor Hardware Configuration ............................................................................... 7 Master Clock Oscillator Hardware Configuration .................................................................................... 7 MCLKOS C Source Selection Jumper Settings ....................................................................................... 8 Input Clock Hardware Configuration...................................................................................................... 9 Input Clock Differential/Single-E nded Mode Selection Jumper Settings ................................................... 9 Output Clock Hardware Configuration ................................................................................................. 10 MA X24000-S eries EVKIT External EEPROM Options .......................................................................... 10 3 MAX24000-SERIES EVALUATION KIT 1. Overview This document covers the revision B assembly of the MA X24000-series E valuation Kit board. 2. Board Floorplan and Configuration Figure 1. MAX 24000-series EVKIT Rev B Board Floorplan USB uP Plug. Pwr Supply Clock Outputs 1-4 Microsemi MAX24310 Clock Outputs 5-6 Clock Inputs MAX24310 EVKIT REV B Clock Outputs 7-10 Oscillator Sites 4 MAX24000-SERIES EVALUATION KIT When the board is oriented as shown in Figure 1, the MAX24000-Series device is located in the middle of the board, the input clock connectors are on the left side, and the output clock connectors are above, to the right and below the device. USB and power supply connectors are located in the top left corner of the board. 2.1 Power Supply Connection The EVKIT board is powered via connector J3 using the provided A C-wall-plug 5V power supply. LED DS1 illuminates to indicat e that the board is powered. 2.2 USB Connection The Windows®-bas ed MA X24000-series EVKIT soft ware communicates to the board via USB connector J4. 2.3 2.3.1 Hardware Configuration Settings Power Supply The EVK IT provides several options for evaluating device performance with respect to power supply configuration. Table 1 summarizes the EVKIT power supply related hardware connectors and functionality. 2.3.2 Reset and Microprocessor The EVK IT provides a momentary switch reset button that can be used to perform a hardware reset of the board. Additionally, the board has a USB connector for interfacing the EVKIT’s microcontroller to the host PC running t he EVKIT soft ware. Table 2 summariz es the EVKIT reset and microprocessor relat ed hardware connectors and functionality. 2.3.3 Master Clock Oscillator The EVK IT provides several options for driving the MA X24000-S eries device’s MCLKOS C input from either an onboard oscillator or an external source. Table 3 summarizes the EVKIT master clock oscillator related hardware configuration connectors and functionality. Table 4 summarizes how to configure the EVK IT jumpers to select each MCLKOS C source. 2.3.4 Input Clocks The EVK IT IC1 and IC2 inputs can be configured to accept either a differential or single-ended signal. When configured as a differential input, that input can be configured as either AC coupled or DC coupled. Table 5 summaries the EVKIT input clock related hardware connectors and functionality. Table 6 summarizes how to configure the EVKIT jumpers for either a differential or single-ended input. 2.3.5 Output Clocks The EVK IT s upports evaluation of all MA X24000-S eries device output clocks using SMB connectors. Table 7 summarizes the EVKIT output clock related hardware connectors. The EVKIT MA X24xxx output clock termination circuits are shown on schematic sheet 11. Common termination options can be evaluated by populating the appropriate components. The EVK IT is provided with out put clocks OC1P/ N through OC8P/ N configured as DC-coupled differential CML, OC9P/N and OC10P/N c onfigured as dual single-ended CMOS. 5 MAX24000-SERIES EVALUATION KIT Table 1. Power Supply Hardware Configuration SILK SCREEN REFERENCE J3 TP2 TP3 DEVICE / FUNCTION BASIC SETTING Power jack Testpoint Testpoint Connected to 5V SCHEMATIC PAGE 3 3 3 GND Testpoint 3 JMP1 3 pin jumper 2-3: V3_3DIG jumpered to V3_3 4 JMP2 3 pin jumper 2-3: V1_8_DIG jumpered to V1_8_D 5 J5 (VDDOA) J6 (VDDOB) J7 (VDDOC) J8 (VDDOD) 10 pin header, power selection Jumper pins 7+8 6 J9 (VSENSEO) 10 pin header, power selection with current measurement Jumper pin 7+8 6 TP.VDDOA TP.VDDOB TP.VDDOC TP.VDDOD Power Testpoint Power Testpoint Power Testpoint Power Testpoint 14 14 14 14 TP.V1_8_ANA_F Power Testpoint 14 TP.VDD_DIG_18 Power Testpoint 14 TP.V3_3_ANA_F Power Testpoint 14 TP.VDD33 Power Testpoint 14 DESCRIPTION 5V power input Testpoint for 5V power input Testpoint for 3.3V supply V3_3 Ground testpoints. Reference designators are not shown, GND designation is used instead Selects source of device VDD33 power pin. This pin can be connected to the board’s main 3.3V supply (V3_3) or to a separately regulated 3.3V supply for the device’s APLLs and XO. Selects source of device VDD_18, VDD_DIG_18 and VDD_OC_18 power pins. These pins can be connected to a digital 1.8V supply (V1_8_D) or to a separately regulated 1.8V supply for the device’s APLLs, XO and outputs. One and only one of the following jumper placements should be used on each 10-pin header: 1-2 Connects VDDOx to V1.5 3-4 Connects VDDOx to V1.8Dig 5-6 Connects VDDOx to V2.5 7-8 Connects VDDOx to V3.3 9-10 VDDOx to VSENSO (see J9) Used to power any of VDDO[A,B,C ,D] when the VSENSO jumper position of J5,J6,J7 or J9 is selected. One and only one of the following jumper placements should be used: 1-2 Connects VSENSO to V1.5 3-4 Connects VSENSO to V1.8Dig 5-6 Connects VSENSO to V2.5 7-8 Connects VSENSO to V3.3 9-10 not used device VDDOA pin device VDDOB pin device VDDOC pin device VDDOD pin device pins: VDD_APLL1_18, VDD_APLL2_18, VDD_XO_18, VDDIO[A,B,C,D] device pins: VDD_OC_18, VDD_DIG_18, VDD_18 device pins: VDD_APLL1_33, VDD_APLL2_33, VDD_XO_33 device VDD_33 pin 6 MAX24000-SERIES EVALUATION KIT Table 2. Reset and Microproce ssor Hardware Configuration SILK SCREEN REFERENCE J4 DEVICE / FUNCTION BASIC SETTING USB connector Connected to PC SCHEMATIC PAGE 8 J1 Bus Connector Not used 8 J14 + DS2,3,4,5 Test points + LED Not used 8 SW1 Reset Not used 8 J2 Debug Not used 8 DESCRIPTION Connects EVKIT to host computer Can be used to interact with an external PCB (as either data source or sink) User I/O pins on microcontroller The PCB receives a power on reset, and subsequent reset is done using SW1. Background debug connector. Used to interface to debug pod part # USBML-12 from PE Micro Table 3. Master Clock Oscillator Hardware Configuration SILK SCREEN REFERENCE DEVICE / FUNCTION BASIC SETTING SCHEMATIC PAGE J53 Header, Power 1-2 9 J44 J46 Header, SMB connector 7-8 9 JMP28 3 pin jumper 2-3 9 DESCRIPTION Provides power to oscillator sites 1-2 powers Y7 3-4 powers Y8 5-6 powers Y9 Selects clock source for UB22 J44 3-4 selects Y9 J44 5-6 selects Y8 J44 7-8 selects Y7 J44 2-4 can be used to route Y7 or Y8 clock signal to SMB J46 J44 1-3, 2-4 can be used to route Y9 to SMB J46 Selects source for device MCLKOSCP/N pins. This revision of the EVKIT does not support MCLKOSCP/N differential options Y6 and J33/J41, and singleended option J33. JMP28 should always be set to positon 2-3. 7 MAX24000-SERIES EVALUATION KIT Table 4. MCLKOS C Source Selection Jumper Settings MCLKOSC Source Y6 On-board 5x7 Differential Oscillator Site Y7 On-board 3x5 Single-ended Oscillator Site Y8 On-board 5x7 Single-ended Oscillator Site Y9 Oscillator Daughter Card Site J33 External Single-ended Input J33/J41 External Differential Input Not Used Jumper Settings This revision of the EVKIT does not support this option. JMP28 = 2-3 J44 = 7-8 J53 = 1-2 JMP28 = 2-3 J44 = 5-6 J53 = 3-4 JMP28 = 2-3 J44 = 3-4 J53 = 5-6 This revision of the EVKIT does not support this option. This revision of the EVKIT does not support this option. JMP28 = 2-3 J44 = Not Installed J53 = Not Installed 8 MAX24000-SERIES EVALUATION KIT Table 5. Input Clock Hardware Configuration SILK SCREEN REFERENCE J22 J21 DEVICE / FUNCTION IC1POS IC1NEG JMP12 J54 JMP13 JMP14 IC1 configuration J27 J30 IC2POS IC2NEG JMP19 J31 JMP17 JMP18 SCHEMATIC PAGE BASIC SETTING IC2 configuratoin Differential, AC Coupled: JMP12 Not Installed J54 = 5-6 JMP13 Installed JMP14 Installed Differential, AC Coupled: JMP19 Not Installed J31 = 5-6 JMP17 Installed JMP18 Installed DESCRIPTION 10 IC1 differential or single-ended input 10 Used to configure IC1 as a differential or single-ended input, AC coupled or DC coupled. Refer to Table 6 for configuration options. 10 IC2 differential or single-ended input 10 Used to configure IC2 as a differential or single-ended input, AC coupled or DC coupled. Refer to Table 6 for configuration options. Table 6. Input Clock Differential/Single-Ended Mode Selection Jumper Settings Input Clock Mode Coupling AC Differential DC IC1 AC Single-ended DC AC Differential DC IC2 AC Single-ended DC Jumper Settings JMP12 = Not Installed J54 = 5-6 JMP13 = Installed JMP14 = Installed JMP12 = Installed J54 = 1-2 JMP13 = Installed JMP14 = Installed JMP12 = Not Installed J54 = 1-3 JMP13 = Not Installed JMP14 = Not Installed JMP12 = Installed J54 = 1-3 JMP13 = Not Installed JMP14 = Not Installed JMP19 = Not Installed J31 = 5-6 JMP17 = Installed JMP18 = Installed JMP19 = Installed J31 = 1-2 JMP17 = Installed JMP18 = Installed JMP19 = Not Installed J31 = 1-3 JMP17 = Not Installed JMP18 = Not Installed JMP19 = Installed J31 = 1-3 JMP17 = Not Installed JMP18 = Not Installed 9 MAX24000-SERIES EVALUATION KIT Table 7. Output Clock Hardware Configuration SILK SCREEN REFERENCE J17 J18 J15 J16 J11 J10 J12 J13 J20 J22 J32 J28 J49 J50 J37 J38 J48 J47 J39 J40 2.4 DEVICE / FUNCTION BASIC SETTING SCHEMATIC PAGE DESCRIPTION 11 Output clocks, referenced to VDDOA 11 Output clocks, referenced to VDDOB 11 Output clocks, referenced to VDDOC 11 Output clocks, referenced to VDDOD OC1 Output OC2 Output OC3 Output OC4 Output OC5 Output OC6 Output OC7 Output OC8 Output OC9 Output OC10 Output GPIO Header and Status LEDs The devic e’s bi-directional GP IO pins are available on the 10-pin header J19. The header pins are labeled for easy identification. The present states of GP IO1 through GP IO4 are indicated by LEDs DS 6 through DS9, respectively. 2.5 Power-up Configuration from Internal/External EEPROM The MA X24000-Series clock synchronization and clock synthesis devices support loading a device configuration from an EEPROM following a hardware reset. Depending on the part number, this EEPROM can be inside the devic e or external. Refer to the Ordering Information table on page 1 and the device data sheets for details. The MA X24000-S eries EVKIT supports evaluating this feature on all devices in the MA X24000-Series family. For devic es that use an external EEPROM two options are provided. Refer to Table 8 for details. For devic es with an internal EEPROM this EVKIT functionality is not used. Table 8. MAX24000-Series EV KIT External EEP ROM Options Option On-board 2048 Byte SOIC EEPROM 8-Pin DIP Socket JMP8 1-2 (SOIC) 2-3 (8-DIP) The MA X24000-Series EVKIT software can be used to program the EEP ROM based on the current GUI configuration, or from a file. Additionally, the EVKIT soft ware can be used to save the current GUI configuration to a file that can be used to program the EEPROM with a third-party tool. Following a hardware reset, the device configuration stored in EEPROM is loaded into t he device if the device pin GPIO3/AC is high. This pin has an internal pull-up resistor. Consequently, if the pin is left floating t he EEP ROM configuration will be loaded following a hardware reset. Placing a jumper across header J19 pins 5 and 6 will hold GPIO3/AC low during reset and prevent the EEPROM configuration from being loaded. 2.6 JTAG Header The device JTAG interfac e is available on the 10-pin header J26. The header pins are labeled with t he corresponding JTAG signal names for easy identification. 10 MAX24000-SERIES EVALUATION KIT 3. Software Installation EVKIT software installation consists of the following two steps: 1. 2. Install the EVKIT software application Install the EVKIT virtual COM port driver (for USB connection to the board) The following sections describe in detail how to perform each of thes e steps. 3.1 Software Application Installation At this time the EVKIT software is only supported on Windows® XP and Windows® 7 operating systems. To install the software, open the installer zip file and run setup.exe. The EVK IT software requires Microsoft .NE T Framework 4.0 to operate. When setup.exe is run, it checks to see if .NET 4.0 is installed on the target computer. If . NE T 4.0 is not already installed, the user is prompted t o download and install .NE T 4.0 from Microsoft’s website. 3.2 USB Virtual COM Port Device Driver Installation After the GUI application has been installed on the PC, apply power to the EVKIT board and connect its USB port to a USB port of the PC. Then follow these steps: ♦ A "Found New Hardware" message will appear in the notification area of the Windows taskbar, and then the Found New Hardware Wizard will appear. ♦ Select No when asked if you want to connect to Windows Updat e to look for the driver. ♦ Click Next. ♦ Select Install from a list or specific location. ♦ Click Next. ♦ Select Search for the best driver in these locations and check include thi s location in the search then browse to the folder where the software was installed. The default installation folder can be reach by browsing: Windows XP: My Computer  Program Files  Microsemi  MA X24000-Series EVKIT Windows 7: Computer  Local Disk (C:)  Program Files (x86) Microsemi  MA X24000-S eries EVKIT Within this directory select the sub-directory US B Dri ver. The driver file is: Freescale_CDC_Driver_CMX_W IN7.inf, but Windows only needs to know the name of the folder in which to look for this file. ♦ Click Next. ♦ If a message appears indicating the software has not passed logo testing, click Continue Anyway. That should complete the virt ual COM port device driver installation. After following these steps, the EVK IT software should be ready to communicate with the board. 11 MAX24000-SERIES EVALUATION KIT 3.3 Command Line Options The soft ware has these command line options: -l specifies an alternate log file. Example: MA X24000S eriesEVKIT.exe –l “mylog.mfg” To add command line options to the EVKIT shortcut that the installer adds to t he desktop or the start menu, rightclick on the shortcut and select Propertie s. In the Shortcut tab, at the end of the text in the Target textbox, add a space followed by the command line option. 4. Software Application Overview The EVKIT soft ware provides an easy and interactive way to evaluate the MA X24000-Series clock synchronization and clock synthesis devices by using hierarchical menus to configure the device and monitor its status. The following sections briefly describe each of the major application menus. Note: in each menu, when the mouse cursor i s placed over a configuration or status field, more information is di splayed about that field such a s the associated device register(s), valid numerical range, or error information. 4.1 Main Menu A customized main menu is displayed for each MA X24000-Series device. The Select Device button in the lower left corner of the menu can be used to select a specific device in the MA X24000-S eries family. The EVKIT main menu for the MA X24310 revA1 is shown in Figure 2. This menu provides an overview of the MA X24310A1 configuration and status. Additionally, it provides access to the application sub-menus that are us ed to perform detailed device configuration. Figure 2. EVKIT Software Main Menu - MAX24310 Rev B1 12 MAX24000-SERIES EVALUATION KIT The major features located on the main menu are: • Port list (top left) When the program starts, a scan is performed of the computer’s USB -connected virtual COM ports. Those ports connected to a MA X24000-Series EVKIT are displayed in the port list. • Demo Mode checkbox (top center) When the program starts, it is initially in Demo Mode. In Demo Mode the soft ware is not connected to the EVKIT board. In this mode, the software can be used to investigate device configuration options. Additionally, demo mode can be used to develop a device configuration script or EEPROM configuration file. The EVK IT can be operated in demo without the need to connect a board. When the Demo Mode checkbox is unchecked, the EVKIT software establishes communication with t he EVKIT board through the port displayed in the Port box. In this mode all menu configuration changes are translated into register settings which are written to the device on the EVKIT board via the USB interface. • Enable Polling checkbox (top center) While the Demo Mode checkbox is unchecked, if the Enable Polling checkbox is checked, the status registers in the device are periodically polled, and t he corresponding status fields in the GUI are automatically updated. While the Enable Polling checkbox is unchecked, device polling is suspended. • Reset checkbox (top center) This checkbox directly controls the MCR1. RS T bit in the device. When t his box is checked the entire device is reset to its power-on default state. If GP IO3/AC pin is high when reset is de-assert ed, the device automatically configures its registers from internal or external EEPROM (depending on device part number). • Input Clocks, Master Clock Oscillator, and Crystal Oscillator The IC1, IC2, MCLKOS C, and Crystal Oscillator s ections on the main menu are used enable these inputs and specify the signal frequency at the device pin. Simple frequencies such as 156.25MHz can be entered directly in the Frequency edit box. P ressing the Calc button launches a s ub-menu similar to the one shown in Figure 3. This menu can be used to specify more complex frequencies such as 156.25MHz * (255 / 237). In this menu, the nominal frequency numerator and denominator multiplier values can be entered as either simple integer values or as a string of multiplied integer values. Figure 3. Input Clock Frequenc y Calculator Menu 13 MAX24000-SERIES EVALUATION KIT • APLL1 and APLL2 The MA X24000-Series devices have two independently configurable APLLs. Initially, the APLLs are disabled. The EVK IT software indicates this status by disabling the APLLn sub-menu button and the APLL fields on t he main menu. An APLL is enabled by checking its Enable check box on the main menu. The APLL input frequency is automatically determined from the APLL source selected. For output frequency, simple frequencies such as 625MHz can be entered directly in the main menu edit box. Pressing the Calc button launches a sub-menu similar to the one shown in Figure 4. This menu c an be used to specify more complex frequencies such as 625MHz * (255 / 237). From t he specified input and output frequencies, the EVKIT soft ware determines a list of valid configuration options and lists them in the Valid VCO Frequency Configurations list box. In addition the EVKIT soft ware configures the AP LL to the first option in the list. For most applications, the first setting in the list is the optimal configuration. Pressing the APLLn button launches a sub-menu that can be used to configure the APLL manually. This menu can be us ed for detailed custom configuration of an APLL or to see the detailed settings the EVK IT soft ware chose when configuring the APLL from the main menu. Figure 4. APLL1 Output Frequency Calculator Menu • Output Clocks, Bank A through Bank D The MA X24000-S eries devic e output clocks are divided into four banks. These banks and their associated output clocks are shown on the right side of the main menu. The source, signal format, and APLL divisor for each output clock can be specified on t he main menu. Additionally, the frequency of each output clock is displayed on the main menu. The OCn button launches a sub-menu with additional configuration options. • Select Device This button launches a pop-up menu that can be used to select a specific MA X24000-Series device. When a new devic e is selected, the EVKIT soft ware is customized to match that devic e’s features and internal resources. • User Guide Pressing t he User Guide button launches A dobe Acrobat Reader and opens a c opy of the MA X24000-Series EVKIT data sheet (this document). Adobe Acrobat Reader must be installed for this function to work. 14 MAX24000-SERIES EVALUATION KIT • Create Config Script The Create Config Script button launches a sub-menu t hat can be used to save the current GUI configuration to a file. This file is an ASCII text file that contains the sequenc e of device register writes required to configure the device to match the GUI settings. Certain aspects of configuring the device require a specific initialization sequence. The configuration script created using the Create Config Script menu adheres to those requirements. • Run Config Script The Run Config Script button launches a sub-menu that can be used to ex ecute a device configuration script. • Register View The Regi ster View button launches a sub-menu that provides register-level access to all device registers. • View Log File The View Log File button launches a text editor containing the EVKIT soft ware log file. This log file contains the history of all devices register writes performed since the application was launched. • EEPROM The EEP ROM button launches a sub-menu that can be used to perform EEPROM related operations. This menu can be used to save the current GUI configuration to an EEPROM configuration file for later use by either the EVKIT software or a third-party tool. Additionally, this menu can be used to program the EVK IT EEPROM with either the current GUI configuration or an EEPROM configuration file. • I/O Pins The I/O Pins button launches a sub-menu that can be used to configure the device GPIO pin functionality. • Power Meter The Power Meter button launches a sub-menu that displays the devic e estimated and measured power consumption. Esitmated power mode can be us ed in eit her demo mode or while communicating with an EVKIT board. Estimated power is based on data sheet typical and max ratings. Measured power is based on voltage and current measurements taken by the EVK IT board. Measured power mode can only be used while the EVKIT is communicating with an EVKIT board. Note: This measured power mode only reports accurate numbers when board headers J5, J6, J7 and J8 all have jumpers in the SENS O position and header J9 has a jumper in a position ot her than “NA ”. This combination of jumper settings forces all V DDOA through V DDOD power supply voltages to be t he single voltage s pecified by the jumper on header J9. Therefore this feature cannot be used for all possible device configurations. • Di sable All Outputs Pressing the Di sable All Outputs button disables all device outputs. • DPLL This section of the main menu is only displayed for members of the MA X24000-Series devices that contain a DPLL. Initially, the DPLL section of the main menu is disabled. The EVK IT indicates this status by disabling the DPLL sub-menu button and the DP LL fields on the main menu. The DP LL is enabled by checking its Enable check box on the main menu. Prior to enabling the DPLL, its master clock must be configured. This is accomplished by clicking the MCLK button and configuring the fields of the DPLL Master Clock sub-menu. Refer to section 4.4 for details. 15 MAX24000-SERIES EVALUATION KIT The DP LL State, Sel Ref Fail, and Phase Monitor buttons represent latched status bits in the device. When the button is red, the corresponding latched status bit has been set in the device since the last time the button was pressed. Pressing the button clears the latched status bit and changes the color of the button back to green. The State button indicates the state of the DPLL has changed. Sel Ref Fail indicates the selected reference has failed. Phase Monitor indicates the phase monitor limit has been exceeded. The DPLL State, Phase, Freq, Sel Ref, Priority 1, and Priority 2 text boxes display the real-time status of the corresponding devic e register fields. The lower portion of the DPLL s ection of the main menu has fields for the devic e Input Clock Block. Each input clock Status LED displays the real-time status of the input clock as reported by its input monitor. When t he input clock is disabled, the LE D is grey. When the input clock is enabled, the LED provides a color-coded status of the input clock’s state. When a clock of the correct frequency is applied to an input, the associated LED turns yellow when activity is detected and green when the input clock frequency is found to be within range. If an input is disqualified bec ause the DPLL could not lock to it, the LED turns magenta. Pressing the DPLL button launches a sub-menu that can be used to configure the DP LL. Pressing the IC1 or IC2 button launches a sub-menu t hat can be used to c onfigure input monitoring, scaling and dividing for t he corresponding input clock. 16 MAX24000-SERIES EVALUATION KIT 4.2 APLL Configuration Menu The AP LL Configuration sub-menu shown in Figure 5 is accessed by pressing the APLL1 button or the APLL2 button on the main menu. This menu can be used for detailed custom configuration of an APLL or to see the detailed settings the EVKIT soft ware chose when configuring the APLL from the main menu. As shown in Figure 5, each of the Feedback Scale Factor terms (Feedback Multiplier, Fractional Numerator, and Fractional Denominator) can be entered as either simple integer values or as a string of multiplied integer values. Whenever one or more of these fields is change the software colors the Load button red to remind the user that the Feedback Scale Factor field is not updated until the button is clicked. In this menu an APLL can be configured for pin-based input reference selection on the GPIO4/SS pin by checking the External Switching Mode checkbox and specifying the two references to switch between in the APLL Source and Alternate APLL Source fields. Figure 5. APLL1 Configuration Menu 17 MAX24000-SERIES EVALUATION KIT 4.3 Output Clock Configuration Menu The Output Clock Configuration sub-menu shown in Figure 6 is accessed by pressing the corresponding OCn button on t he main menu. This menu is used to configure the output clock signal format and divider values that control the frequency of the clock at the pin. Figure 6. Output Clock Configuration Menu 18 MAX24000-SERIES EVALUATION KIT 4.4 DPLL Master Clock Configuration Menu This sub-menu is only available for MA X24000-Series devices that contain a DP LL. The DPLL master clock configuration sub-menu shown in Figure 7 is accessed by pressing the MCLK button on the main menu. The DPLL master clock can be either sourced directly from t he MCLK OSC pins or synthesized by APLL2 from an input source. This menu is used to specify the source and configure that source to a valid master clock frequency. Once the DP LL master clock configuration is selected, press the OK button t o initialize the DP LL master clock. The DPLL master clock supports three methods of configuration. These methods, as well as simple step-by-step configuration instructions, are shown in the Help section at the bottom of the menu. Each set of instructions is displayed by selecting the corresponding method’s radio button. Figure 7. DPLL Master Clock Configuration Menu 19 MAX24000-SERIES EVALUATION KIT 4.5 DPLL Configuration Menu This sub-menu is only available for MA X24000-Series devices that contain a DP LL. The DPLL configuration sub-menu shown in Figure 8 is accessed by pressing the DPLL button on the main menu. This menu is used to perform detailed configuration of the DP LL including specifying the DPLL bandwidt hs, holdover mode, lock criteria, phase det ector, and phas e buildout functionality. Figure 8. DPLL Configuration Menu 20 MAX24000-SERIES EVALUATION KIT 4.6 DPLL Input Clock Configuration Menu This sub-menu is only available for MA X24000-Series devices that contain a DP LL. The input clock configuration sub-menu shown in Figure 9 can be accessed by pressing the corresponding ICn button on the main menu. This menu is used to perform detailed configuration of input clock functionality related to DPLL operation. This configuration includes enabling the input clock path to the DP LL, specifying the DP LL lock frequency to use for the input clock, and specifying t he divider ratio to be used to divide the input clock to t he lock frequency. This menu can also be used to configure the input clock monitoring parameters. Figure 9. DPLL Input Clock Configuration Menu 21 MAX24000-SERIES EVALUATION KIT 4.7 Power Meter Menu The power meter sub-menu is accessed by pressing the Power Meter button on the main menu. The power met er has two modes of operation – Estimated and Measured. Estimated mode, shown in Figure 10 below, is selected by pressing the Estimated button in the top left corner of the Power Meter menu. In estimate mode, the EVK IT software calculates both the typical and maximum device current and power based on the enabled functionality and device data sheet specs. This mode is available in both Demo Mode and while the EVKIT software is communicating wit h an EVKIT board. Measured mode, shown in Figure 11 below, is selected by pressing the Measured button in the top left corner of the Power Meter menu. In measured mode, the EVKIT s oft ware periodically measures the current of the device on the EVKIT and displays this information along with the corresponding calculated supply power and total device power. This information can be us ed t o estimate the typical devic e power consumption for a specific device configuration. Meas ured mode is only available while the EVKIT software is communicating with an EVKIT board. Note: This feat ure only reports accurate numbers when board headers J5, J6, J7 and J8 all have jumpers in the SENSO position and header J9 has a jumper in a position other than “NA”. This combination of jumper settings forces all VDDOA through V DDOD power supply voltages to be the single voltage specified by the jumper on header J9. Therefore this feature cannot be used for all possible device configurations. Figure 10. Power Meter Menu, Estimated Mode 22 MAX24000-SERIES EVALUATION KIT Figure 11. Power Meter Menu, Measured Mode 23 MAX24000-SERIES EVALUATION KIT 4.8 I/O Pin Configuration Menu The I/O Pin Configuration sub-menu shown in Figure 12 is accessed by pressing the I/O Pins button on the main menu. This menu is used to configure devic e’s four GP IO pins. Each I/O pin can be configured to map a device status register bit to the pin, drive a 0 or 1, or be an input pin. A dditionally this menu can be used to configure t he output to be invert ed or open-drain. Output signal inversion c an only be applied to a GP IO pin that is configured to output the state of a status register bit. Figure 12. I/O Pin Configuration Menu 24 MAX24000-SERIES EVALUATION KIT 4.9 EEPROM Menu The EEPROM sub-menu shown in Figure 13 is accessed by pressing the EEP ROM button on the main menu. This menu can be us ed to save the current GUI configuration to an EEPROM configuration file for later use by either the EVKIT software or a third-party tool. Additionally, this menu can be used to program the EVKIT EEPROM with either the current GUI configuration or an EEP ROM configuration file. The EVKIT software must be connected to an EVKIT board and not be in demo mode to program the EEPROM. However, an EEPROM configuration file can be created in demo mode or when connected to an EVKIT board. Figure 13. EEPROM Menu 25 MAX24000-SERIES EVALUATION KIT 4.10 Register View Menu When the main menu Register View button is pressed, the Register View window s hown in Figure 14 is launched. This window can be used to view and edit the entire device register set. The large grid that takes up most of the window displays the device register map. For eac h register, its hexadecimal address in square brackets is followed by its register name and its contents in two-digit hex format. When a register is clicked in the main register grid, its register description and fields are displayed at the bottom of the window. The Register View window supports the following actions: ♦ ♦ ♦ ♦ ♦ ♦ ♦ Read a register. Select the register in the register map. Read a register field. Select the register in the map or the register field at the bottom of the window. Read all registers. Press the Read All button. Write a register. Double-click the register name in the register map and enter the value to be written. Write a register field. Select the register, double-click the field, and enter the value to be written. Write a multi-register field. Double-click one of the register names and enter the value for the field. Write a complete device register dump to a text file. Press the Register Dump button. When using the Register View window it is important to remember that APLL, output clock, and input clock registers are bank-s witched by the APLLSEL (0x0010), OCSEL (0x00C0), and ICSEL (0x0050) registers, respectively. Refer to the device data sheet register map for more details. It is also important to remember that all DPLL and Input Clock Block registers are only accessible if these blocks have been provided a valid master clock. Figure 14. Register View Menu 26 MAX24000-SERIES EVALUATION KIT 4.11 Configuration Scripts and Log Files 4.11.1 Configuration Log File E very write command issued by the software to the EVKIT board is logged in a file. The file naming convention for the default log file name is [DEV ICE][REV]_EVK IT_Log.mfg. The default location of t he log file is the application data directory specified when the EVK IT soft ware is installed. As an example, if the default application data directory is chosen when the EVK IT software is installed and the selected device is a MA X24310 revA1, t he corresponding log file would be: Windows XP: C:\Documents and Settings\All Users\Application Data\Microsemi\MA X24000-Series EVKIT\MA X24310A 1_EVKIT_Log.mfg Windows 7: C:\Users\\AppData\Local\Microsemi\MA X24000-Series EVKIT\MA X24310A 1_EVKIT_Log.mfg The log file can be viewed in Notepad by pressing the Log File button in the lower-left corner of the main window. Command line option "-l " can be used to change the log file name and location. 4.11.2 Configuration Scripts Configuration scripts are useful for quickly configuring a devic e without having to remember all the required settings. Two types of configuration scripts are possible: full and partial. A full configuration script contains register writes for all configuration registers in the device. A partial configuration script contains register writes for only those registers that have been changed from their reset values. A partial configuration script can be used to initialize a device following reset using the minimum number of devic e accesses. Cert ain aspects of c onfiguring a MA X24000-Series device require a specific initialization sequence. The configuration scripts created using the Create Config Script menu adhere to those requirements. 4.11.2.1 Device Initialization Script The devic e initialization script contains an application independent devic e configuration that optimizes device performance. Each MA X24000-S eries device has a unique initialization script file. This script should be loaded as the first step in device configuration as described in the following sections. The initialization script file name is [DEVICE][REV IS ION]_Startup.mfg (where [ DEVICE] indicates device part number and [ REVIS ION] indicates devic e revision. All devic e startup configuration scripts are located in the application data directory in the subdirectory Scripts\Startup Scripts. As an example, the initialization script file for the MA X24310 revA1 is: Windows XP: C:\Documents and Settings\All Users\Application Data\Microsemi\24000-Series EVKIT\Scripts\Startup Scripts\MAX24310A 1_Startup.mfg Windows 7: C:\Users\\AppData\Local\Microsemi\MA X24000-Series EVKIT\Scripts\Startup Scripts\MAX24310A 1_Startup.mfg 27 MAX24000-SERIES EVALUATION KIT The startup configuration script can be edited or replaced as needed t o change the initial configuration of t he devic e. Be aware, however, that the section of the file labeled “Required Initialization” must be executed aft er devic e power-up or reset for the device to operate correctly. 4.11.2.2 Creating a Full Configuration Script in Demo Mode Perform the following sequence to create a full configuration script in Demo Mode: 1. Start the EVKIT soft ware 2. Load the appropriate device initialization script using the Run Config Script button 3. Configure the device using the EVKIT software GUI menus 4. Press the Create Config Script button in the lower-left corner of the main menu 5. On the Create Config Script pop-up menu, specify the file name and location, and check the Include configuration regi sters that are still set to their reset value s checkbox 6. On the Create Config Script pop-up menu, press the Create button If the specified file already exists, a pop-up message is displayed to confirm that the file should be overwritten. After the configuration file is created, it is displayed in Notepad for review. 4.11.2.3 Creating a Partial Configuration Script in Demo Mode Perform the following sequence to create a full configuration script in Demo Mode: 1. Start the EVKIT soft ware 2. Load the appropriate device initialization script using the Run Config Script button 3. Configure the device using the EVKIT software GUI menus 4. Press the Create Config Script button in the lower-left corner of the main menu 5. On the Create Config Script pop-up menu, specify the file name and location, and un-check the Include configuration regi sters that are still set to their reset value s checkbox 6. On the Create Config Script pop-up menu, press the Create button If the specified file already exists, a pop-up message is displayed to confirm that the file should be overwritten. After the configuration file is created, it is displayed in Notepad for review. 28 MAX24000-SERIES EVALUATION KIT 4.11.2.4 Creating a Full Configuration Script While Communicating With an EVKIT Perform the following sequence to create a full configuration script while communicating with an EVKIT: 1. Start the EVKIT soft ware 2. Uncheck the Demo Mode check box in the upper left section of the main menu 3. On the Run Config Script pop-up menu, press the Initialize button to load the device initialization script 4. Configure the device using the EVKIT software GUI menus 5. Press the Create Config Script button in the lower-left corner of the main menu 6. On the Create Config Script pop-up menu, specify the file name and location, and check the Include configuration regi sters that are still set to their reset value s checkbox 7. On the Create Config Script pop-up menu, press the Create button If the specified file already exists, a pop-up message is displayed to confirm that the file should be overwritten. After the configuration file is created, it is displayed in Notepad for review. 4.11.2.5 Creating a Partial Configuration Script While Communicating With an EVKIT Perform the following sequence to create a full configuration script while communicating with an EVKIT: 1. Start the EVKIT soft ware 2. Uncheck the Demo Mode check box in the upper left section of the main menu 3. On the Run Config Script pop-up menu, press the Initialize button to load the device initialization script 4. Configure the device using the EVKIT software GUI menus 5. Press the Create Config Script button in the lower-left corner of the main menu 6. On the Create Config Script pop-up menu, specify the file name and location, and un-check the Include configuration regi sters that are still set to their reset value s checkbox 7. On the Create Config Script pop-up menu, press the Create button If the specified file already exists, a pop-up message is displayed to confirm that t he file s hould be overwritten. After the configuration file is created, it is displayed in Notepad for review. 4.11.2.6 Running a Configuration Script Perform the following sequence to run a configuration script 1. Press the Run Config Script button in the lower-left corner of the main window 2. On the Run Config Script pop-up menu, specify the file name and location 3. On the Run Config Script pop-up menu, press the Execute button. A configuration script can be run while in Demo Mode or communicating with an EVKIT. 29 MAX24000-SERIES EVALUATION KIT 4.11.2.7 EVKIT Log File Whle the EVKIT soft ware is running, a log file is maintained of all device configurations that are performed. This includes any GUI menu updates that c orrespond to device register writes as well as any register writes performed whn a configuration script is run. The log file can be viewed by pressing the View Log File button at the bottom of the main menu. This log file should not be used as a substitute for the device configuration script created using t he Create Config Script button as described above in this section. 5. EVKIT Errata None. 6. Revision History REVISION DATE 12/20/ 12 DESCRIPTION First version for EVKIT revB assembly 30 MAX24000-SERIES EVALUATION KIT 7. Bill of Materials Figure 15. EVKIT Bill of Materials DESIGNATION QTY DESCRIPTION SUPPLIER PART Common Components B1, B2, B3, B4, B5, B6, B7, B8, B9, B10, FB1, FB2, FB3, FB4 C19, C20, C21, C22, C23, C26, C27, C29, C30, C35, C36, C38, C39, C41, C42, C43, C44, C45, C47, C58, C60, CB61, CB117, CB169 C14, C28, CB5, CB8, CB11, CB12, CB18, CB19, CB48, CB54, CB55, CB65, CB71, CB73, CB74, CB76, CB77, CB78, CB79, CB81, CB82, CB84, CB93, CB99, CB115, CB129, CB139, CB140, CB142, CB143, CB144, CB147 C15, C54, CB23, CB28, CB40, CB66, CB67, CB68, CB69, CB70, CB83, CB146, CB151 C7, C8, C9, C10, C13, C17, CB7, CB9, CB13, CB17, CB21, CB24, CB30, CB32, CB34, CB35, CB36, CB38, CB56, CB57, CB63, CB72, CB125, CB137 C11, C12, C16, C18, C24, C31, C32, C33, C37, C46, C48, C49, C50, C52, C53, C55, C56, C57, C59, C61, C62, CB37, CB39, CB41, CB42, CB43, CB44, CB45, CB47, CB49, CB50, CB51, CB52, CB53, CB58, CB64, CB94, CB95, CB98, CB102, CB103, CB104, CB106, CB107, CB108, CB110, CB111, CB112, CB113, CB116, CB119, CB120, CB123, CB124, CB127, CB128, CB130, CB131, CB136, CB145, CB149, CB154, CB155, CB158, CB162, CB163, CB164, CB165 C51, CB148, CB153 CB20 C25, C34, C40, C63, C65, CB6, CB10, CB14, CB15, CB16, CB22, CB26, CB29, CB33, CB46, CB59, CB60, CB62, CB75, CB80, CB86, CB87, CB88, CB89, CB90, CB91, CB92, CB97, CB105, CB118, CB122, CB126, CB132, CB133, CB134, CB135, CB138, CB141, CB150, CB152, CB160 CB156, CB157, CB159, CB166, CB167, CB168 CB161 14 GHZ NOISE CHIP FERRITE BEAD, .25 OHM DC, 600 OHM @100MHz, 600 OHM @1GHz, 800mA 24 MURATA BLM18HE601SN1D CAP CER 3.3UF 4.0V X5R 0402 AMK AMK105BJ335MV-F 32 0603 CERAM 1.0uF 6.3V 10% MULTILAYER PAN ECJ-1VB0J105K 13 L_0603 CERAM .1uF 16V 20% X7R AVX 0603YC104MAT 24 0603 CERAM 10uF 6.3V 20% MULTILAYER PAN ECJ-1VB0J106M 68 0402 CERAM 0.1uF 16V 10% PAN ECJ-0EB1C104K 3 1 L_0603 CERAM .001uF 50V 10% CAPACITOR, TANT 68uF 16V 20% PAN NICHICON ECJ-1VB1H102K F931C686MNC 41 0603 CERAM 4.7uF 6.3V 10% MULTILAYER PAN ECJ-1VB0J475K 6 L_0603 CERAM .01uF 50V 10% X7R AVX 06035C103KAT 1 D CASE TANT 68uF 16V 20% PAN ECS-T1CD686R 31 MAX24000-SERIES EVALUATION KIT DESIGNATION QTY DESCRIPTION CB25, CB27 CB31 DB3, DB6 2 1 2 DB1, DB2, DB4, DB5 4 DS1, DS4, DS5 DS2, DS3, DS6, DS7, DS8, DS9, DS10 TP12, GND_TP2, GND_TP3, GND_TP4, GND_TP5, GND_TP6, GND_TP7 HB1, HB2, HB3, HB4, HB5, HB6, HB7, HB8, HB9, HB10, HB11 J1, J14, J19 J2 J3 J31, J36, J45, J53, J54 J4 J5, J6, J7, J8, J9, J26, J44 JMP1, JMP2, JMP3, JMP4, JMP5, JMP6, JMP8, JMP10, JMP23, JMP24, JMP25, JMP26, JMP28, JMP30 JMP7, JMP9, JMP11, JMP12, JMP13, JMP14, JMP17, JMP18, JMP19, JMP27, JMP29, JMP31, JMP32 R51, R52, R63, R64, R65, R66, R67, R68, R69, R70, R71, R72, R73, R74, R75, R76, R77, R78 R79, R80, R81, R82 R15, R16, R17, R19 RB13, RB15, RB16, RB19, RB30, RB31, RB32, RB38 R28, R29, R34, R35, R41, R42, R56, R57 R3, RB20, RB22, RB25, RB26, RB33 R4, R6, R26, R27, R53, R54, RB1, RB2, RB28, RB29, RB36, RB40 R45, RB34, RB37 R5, RB3, RB4, RB8, RB9, RB11 C52, R7, R8, R9, R10, R11, R12, R13, R14, R18, R20, R21, R22, R30, R31, R32, R33, R36, R37, R38, R39, R46, R47, R48, R49, R50, R55, R58, R148, RB39, RB42 RB10 RB12, RB14, RB17, RB18, RB21, RB23, RB24, RB27 RB5, RB6 RB7 SW1 TP2, TP3, TP4, TP5, TP7, TP8, TP9, TP10, TP11 3 0603 CERAM 22pF 50V 5% 0805 CERAM .47uF 16V 10% DIODE 1A 50V SMD SCHOTTKY DIODE, 1 AMP 40 VOLT (OK TO SUBSTITUTE Vishay VS-10BQ040PBF) L_LED, GREEN, SMD 7 LED, RED, SMD 7 STANDARD GROUND CLIP 11 Rubber bumper 0.5 inch 3 1 1 5 1 7 L_TERMINAL STRIP, 10 PIN, DUAL ROW, VERT L_TERMINAL STRIP, 6 PIN, DUAL ROW, VERT 2.0MM SURFACE MOUNT POWER JACK TERMINAL STRIP, 6 PIN, DUAL ROW, V ERT CONN, USB, TYPE B SINGLE RT ANGLE TERMINAL STRIP, 10 PIN, DUAL ROW, V ERT 14 SUPPLIER PART PAN PAN DIODES INC ECJ-1VC1H220J ECJ-2YB1C474K S1AB-13-F IRF 10BQ040PBF PAN LN1351C PAN LN1251C KEYSTONE 4954 NA SJ5518-0 STC STC CUI INC STC MOL NA TSW-105-07-T-D TSW-103-07-T-D PJ-002AH-SMT TSW-103-07-T-D 67068-8000 NA L_HEADER, 3- PIN, .100 CENTERS, VERTICAL STC TSW-103-07-T-S 13 L_2 PIN HEADER, .100 CENTERS, VERTICAL STC TSW-102-07-T-S 18 RES 0402 30.0 OHM 1/16W 1% PAN ERJ-2RKF30R0X 4 4 RES 0402 30.0 OHM 1/16W 1% RES 0603 0.0 Ohm 1/16W 5% PAN PAN ERJ-2RKF30R0X ERJ-3GEY0R00V 8 RES 0402 1.00 KOHM 1/16W 1% PAN ERJ-2RKF1001X 8 RES 0402 49.9 OHM 1/16W 1% PAN ERJ-2RKF49R9X 6 RES 0603 332 Ohm 1/16W 1% PAN ERJ-3EKF3320V 12 RES 0603 10.0K Ohm 1/16W 1% PAN ERJ-3EKF1002V 3 RES 0402 100 OHM 1/16W 1% 6 Current Sensing Resistor 0.02 ohm PAN ERJ-2RKF1000X Ohmite LVK12R020DERCT- ND 31 RES 0402 0 OHM 1/10W 5% PAN ERJ-2GE0R00X 1 RES 0603 100K Ohm 1/16W 1% PAN ERJ-3EKF1003V 8 RES 0603 330 Ohm 1/16W 5% PAN ERJ-3GEYJ331V 2 1 1 RES 0603 33.2 Ohm 1/16W 1% RES 0603 1.00M Ohm 1/16W 1% SWITCH MOM 4PIN SINGLE POLE PAN PAN PAN ERJ-3EKF33R2V ERJ-3EKF1004V EVQPAE04M 9 TESTPOINT, 1 PLATED HOLE RED KEYSTONE 5000R FREESCALE MC9S08JM32CLH-ND Maxim MAX MAX9111EKA+ MAX1793EUE33/V+-ND MAXIM MAX9610FEXK+T MAX MAX1793EUE-15 U1 1 UB20 UB5, UB6, UB13, UB21 U2, UB1, UB2, UB7, UB8, UB14 UB10 1 4 IC, HCS08 8-BIT MICROCONTROLLER, 32K FLASH, 2K RAM, 2 UART, 2 SPI, I2C, USB, -40 TO 85C, 64 PIN LQFP Single/Dual LVDS Line Receiver LINEAR REGULATOR, 3.3V, 16 PIN TSSOP- EP 6 Precision Current-Sense Amplifier 1 LINEAR REGULATOR, 1.5V, 16 PIN TSSOP- EP 32 MAX24000-SERIES EVALUATION KIT DESIGNATION QTY UB11 1 UB12 1 UB15, UB16, UB17, UB18, UB19 5 UB23 1 UB3, UB4 2 UB9 1 X1 1 Y9 1 J10, J11, J12, J13, J15, J16, J17, J18, J20, J21, J22, J23, J24, J25, J27, J28, J29, J30, J32, J33, J34, J35, J37, J38, J39, J40, J41, J42, J43, J46, J47, J48, J49, J50, J51, J52 36 DESCRIPTION MICROPROCESSOR VOLTAGE MONITOR, 3.08V RESET, 4PIN SOT143, LEAD-FREE ULTRA-HIGH- PRECISION, ULTRA-LOW-NOISE SERIES VOLTAGE REFERENCE, 4.096V, 8 PIN UMAX HIGH SPEED BUFFER Low-Voltage DDR Linear Regulators Sink, Source up to 3A LINEAR REGULATOR, 1.8V, 16 PIN TSSOP- EP, ROHS/LEAD-FREE LINEAR REGULATOR, 2.5V, 16 PIN TSSOP- EP XTAL, HC49SD, 12.0000MHz +/-50PPM, CL=20PF VECTRON OSC OUTLINE WITH TERMINAL SOCKET, 10-PIN, 2 ROW VERTICAL. CONNECTOR, SMB, 50 OHM V ERTICAL, 5PIN SUPPLIER PART MAX MAX811TEUS+T MAX MAX6126BASA41+ FAIRCHILD NC7SZ86 MAXIM MAX1510ETB+ MAX MAX1793EUE18+ MAX MAX1793EUE-25+ FOX FOXSDLF-120-20 STC SSW-105-01-T-D AMP 413990-1 MICROSEMI MAX24210EXG+ RAKON TX6287-20.480M VECTRON VCC1-1541-98M304000 ATM 8 DIP SOCKET MAX24210 EVKIT Specific Components U5 1 Y7 1 Y8 1 Y4 1 U3 1 NA 1 10-Output Any-Rate Timing IC OSC ILLATOR, RAKON TCXO, 3.3V, 20.48 MHZ, 3mmX5mm SMD OSCILLATOR, VECTRON XO, 3.3V, 98.304MHZ, 4 PIN 5x7mm SMD 8 PIN DIP SOCKET SPI SERIAL EEPROM 2M 8 PIN SOIC 2.7V TO 3.6V 49.152MHz Crystal Daugher Card ATMEL AT25160B-SSHL-B MICROSEMI Figure 17 MICROSEMI MAX24310EXG+ RAKON TX6287-20.480M VECTRON VCC1-1541-98M304000 MICROSEMI Figure 17 MICROSEMI MAX24410EXG+ VECTRON VCC1-1539-78M1250000 ATM 8 DIP SOCKET MAX24310 EVKIT Specific Components U5 1 Y7 1 Y8 1 NA 1 10-Output Any-Rate Timing IC w ith Internal EEPROM OSC ILLATOR, RAKON TCXO, 3.3V, 20.48 MHZ, 3mmX5mm SMD OSCILLATOR, VECTRON XO, 3.3V, 98.304MHZ, 4 PIN 5x7mm SMD 49.152MHz Crystal Daugher Card MAX24410 EVKIT Specific Components U5 1 Y8 1 Y4 1 U3 1 NA 1 10-Output Any-Rate Clock Multiplier OSCILLATOR, VECTRON XO, 3.3V, 78.125MHZ, 4 PIN 5x7mm SMD 8 PIN DIP SOCKET SPI SERIAL EEPROM 2M 8 PIN SOIC 2.7V TO 3.6V 50MHz Crystal Daugher Card ATMEL AT25160B-SSHL-B MICROSEMI Figure 16 MICROSEMI MAX24510EXG+ VECTRON VCC1-1539-78M1250000 MICROSEMI Figure 16 MAX24510 EVKIT Specific Components U5 1 Y8 1 NA 1 10-Output Any-Rate Clock Multiplier w ith Internal EEPROM OSCILLATOR, VECTRON XO, 3.3V, 78.125MHZ, 4 PIN 5x7mm SMD 49.152MHz Crystal Daugher Card 33 MAX24000-SERIES EVALUATION KIT MAX24610 EVKIT Specific Components U5 1 Y7 1 Y8 1 Y4 1 U3 1 NA 1 10-Output Any-Rate Line Card Timing IC OSC ILLATOR, RAKON TCXO, 3.3V, 20.48 MHZ, 3mmX5mm SMD OSCILLATOR, VECTRON XO, 3.3V, 98.304MHZ, 4 PIN 5x7mm SMD 8 PIN DIP SOCKET SPI SERIAL EEPROM 2M 8 PIN SOIC 2.7V TO 3.6V 49.152MHz Crystal Daugher Card MICROSEMI MAX24610EXG+ RAKON TX6287-20.480M VECTRON VCC1-1541-98M304000 ATM 8 DIP SOCKET ATMEL AT25160B-SSHL-B MICROSEMI Figure 17 MICROSEMI MAX24710EXG+ RAKON TX6287-20.480M MAX24710 EVKIT Specific Components U5 1 Y7 1 Y8 1 NA 1 10-Output Any-Rate Line Card Timing IC w ith Internal EEPROM OSC ILLATOR, RAKON TCXO, 3.3V, 20.48 MHZ, 3mmX5mm SMD OSCILLATOR, VECTRON XO, 3.3V, 98.304MHZ, 4 PIN 5x7mm SMD 49.152MHz Crystal Daugher Card VECTRON VCC1-1541-98M304000 MICROSEMI Figure 17 VECTRON AVX PAN PAN VXM7-1148-50M000000 06031U160FAT2A ERJ-3EKF1004V ERJ-3EKF1211V VECTRON AVX PAN PAN VXM7-1149-49M152000 06031U160FAT2A ERJ-3EKF1004V ERJ-3EKF1211V Figure 16. EVKIT 50MHz Crystal Daughter Card Bill of Materials 50MHz Crystal Daugher Card XDC_X1 XDC_C1, XDC_C2 XDC_R1 XDC_R2 1 2 1 1 Crystal, 50MHz +/-20ppm, CL=10pf Capacitor, ceramic, 16PF, 100V, 1%, 0603 RES 0603 1.00M Ohm 1/16W 1% RES 0603 1.21M Ohm 1/16W 1% Figure 17. EVKIT 49.152MHz Crystal Daught er Card Bill of Materials 49.152MHz Crystal Daugher Card XDC_X1 XDC_C1, XDC_C2 XDC_R1 XDC_R2 1 2 1 1 Crystal, 49.152MHz +/-20ppm, CL=10pf Capacitor, ceramic, 16PF, 100V, 1%, 0603 RES 0603 1.00M Ohm 1/16W 1% RES 0603 1.21M Ohm 1/16W 1% 8. Schematics See the following pages. 34 8 7 6 5 4 3 2 1 D D C C B B A A TITLE: DATE: MAX24310 REV B ENGINEER: 8 7 6 5 4 3 12-20-2012 PAGE: 2 1 OF 15 1 8 7 6 5 4 3 2 1 RB30 1.00K V3_3 D 3 OC9NEG F2 MCLKOSCN OC8POS J1 OC8NEG H1 OC7POS J2 OC7NEG H2 OC6POS J3 OC6NEG H3 OC5POS J7 OC5NEG H7 OC4POS J8 OC4NEG H8 OC3POS J9 OC3NEG H9 OC2POS F9 OC2NEG F8 OC1POS E9 OC1NEG E8 IC2POS B1 IC2NEG C A9 IC1POS B9 U5 SPI1_MISO SPI1_MOSI SPI1_SCK RST_811* GPIO4 B2 CS_N GPIO3 A2 A5 SDO GPIO2 B8 A7 SDI GPIO1 A8 A6 SCLK RST_N JTRST_N C6 C8 JTMS C7 JTCLK B5 JTDI C5 JTDO B6 JTRST JTMS JTCLK JTDI JTDO 2 TMS 4 6 V3_3 VCC 1 TCK 3 3 TDI RST 5 8 TDO 7 7 10 10 GND 9 C CONN_10P JTRST JTCLK RB38 1.00K RB36 10.0K EEPROM SOCKET+SOIC PAGE 7 2 R148 B 1.00M XDC_X1 XDC_R2 YB1 16PF XDC_C2 16PF XDC_C1 DNP 6 5 A DS10 50MHZ TITLE: DATE: REV B ENGINEER: 7 UB194 49.152MHZ MAX24310 8 1 2 ECS_N MAX24405 MAX24410 MAX24505 MAX24510 CASE 18PF CB100 4 2 18PF CB121 DNP GND=GND NC7SZ86_U BUFFER RED 3 CASE XDC_X1 FREQ MAX24205 MAX24210 MAX24305 MAX24310 MAX24605 MAX24610 MAX24705 MAX24710 332 XDC_R2 DEVICE RB33 DAUGHTER CARD XTAL CIRCUIT 11 1 XOUT EVKIT ONBOARD XTAL CIRCUIT REPLACED BY DAUGHTER CARD XTAL CIRCUIT DNP 50.0000MHZ A XIN 2 EVKIT ONBOARD XTAL CIRCUIT 1.21K XOUT XIN XOUT J5 XIN H5 B GPIO4 GPIO3 GPIO2 GPIO1 J26 XOUT XIN IC1NEG MAX24310 B7 1 MCLKOSCP B3 2 JMP10 SPI1_SS* 0.0 F1 1 E2 OC9POS A3 A1 IC1POS IC1NEG OC10NEG OC10POS OC10NEG OC9POS OC9NEG OC8POS OC8NEG OC7POS OC7NEG OC6POS OC6NEG OC5POS OC5NEG OC4POS OC4NEG OC3POS OC3NEG OC2POS OC2NEG OC1POS OC1NEG ESDO ESDI ESCLK ECS_N TEST IC2POS IC2NEG E1 ESDO C4 ESDI B4 ESCLK A4 ECS_N C3 C2 TEST MCLKOSCPOS MCLKOSCNEG OC10POS D U5 MAX24310 4 3 12-20-2012 PAGE: 2 2 OF 15 1 3 2 UB14 1 50V/V OUT MAX9610 GND GND V3_3_OSC 2 4 1 1 C13 2 RB11 1 B5 2 2 SHDN* CB55 RST* 6 7 1.0UF 15 2 14 OUT4 3 B6 2 OUT3 IN4 10UF 2 IN3 5 CB63 4.7UF CB46 1 C28 4 V3_3_OSC_F 1 2 13 1 12 OUT2 0.02 10UF OUT1 IN2 1 IN1 3 2 2 GREEN 1.0UF 1 4.7UF C25 + 2 68UF 11 CB20 332 1 NC DS1 2 2 R3 1 BARREL DB3 4 1 2 CENTER POST 2 1 2 J3 R_SENSE 1 UB13 TP2 D 4 1 5 V5_0 VSENSE_33OSC 1 2 RS- RS+ D 3 4.7UF 4 CB150 5 2 6 1.0UF 7 CB65 8 3 C SET 11 GND 10 C MAX1793_U2 VCC UB5 2 IN1 OUT1 12 3 IN2 OUT2 13 4 IN3 OUT3 14 5 IN4 OUT4 15 RST* 6 V3_3 TP3 1 10UF CB36 2 2 CB15 4.7UF 1 GND_TP5 GND_TP6 GND_TP4 GND_TP2 GND_TP3 3.3V B 7 SHDN* SET 11 GND 10 B MAX1793_U2 3.3V UB6 V3_3_ANA IN1 OUT1 12 3 IN2 OUT2 13 4 IN3 OUT3 14 5 IN4 OUT4 15 RST* 6 7 SHDN* 1 A 2 10UF CB16 2 1 4.7UF 2 CB26 1 4.7UF CB62 2 2 CB86 4.7UF 1 V3_3 CB34 A 4.7UF 1 2 SET 11 GND 10 TITLE: MAX1793_U2 8 7 6 5 DATE: MAX24310 3.3V 4 REV B ENGINEER: 3 12-20-2012 PAGE: 2 3 OF 15 1 5 4 50V/V OUT UB1 MAX9610 GND GND V3_3 10UF 1 1 RB3 2 2 VDD33 1 3 2 1 1.0UF C7 CB12 1 0.02 4 V3_3_ANA D 4 R_SENSE 1 2 JMP1 VSENSE_33DIG 1 2 CB5 3 5 2 1 RS- RS+ V3_3_DIG 3 2 4.7UF D 3 CB97 6 2 7 1.0UF 8 C C B B 50V/V OUT UB8 MAX9610 GND GND 4 2 TITLE: 6 1 4.7UF 2 CB92 1 1.0UF 2 CB79 1 4.7UF REV B ENGINEER: 7 2 DATE: MAX24310 8 CB91 1 1.0UF 2 CB81 1 2 4.7UF CB138 1 1.0UF CB140 2 1.0UF CB74 2 2 2 1 1 CB54 2 1 TP4 2 1 B3 1 1 10UF 3 B4 RB9 10UF CB19 1.0UF C10 1 4 A V3_3_ANA_F 1 C17 0.02 2 R_SENSE 1.0UF 2 VSENSE_33ANA 1 2 RS- RS+ 5 V3_3_ANA 3 5 4 3 12-20-2012 PAGE: 2 4 OF 15 1 A 8 7 6 5 4 3 2 1 NOTES: 1. CB109 IS NOT POPULATED TO PROVIDE A CLEAR MOUNTING AREA FOR THE CRYSTAL DAUGHTER CARD D D 50V/V OUT UB2 MAX9610 GND GND VSENSE_18DIG 1 2 1 2 4.7UF CB118 1 2 1.0UF CB115 1 2 4.7UF CB105 1 1.0UF 2 CB93 1 4.7UF 2 VDD_DIG_18 1.0UF CB129 1 3 C 1 1.0UF CB99 10UF CB125 1 10UF 1 TP5 RB4 2 2 2 2 CB11 1.0UF C8 1 4 2 1 V1_8_ANA 0.02 1 2 JMP2 C 4 R_SENSE 1.0UF 2 2 5 CB8 3 V1_8_DIG CB135 1 RS- RS+ V1_8_D 3 B B 1 2 4.7UF CB122 1 1.0UF 2 CB139 CB144 1 4.7UF 4.7UF CB134 2 CB87 1 1.0UF 1.0UF CB147 2 4.7UF 1 1 1.0UF 4.7UF DNP CB84 1 CB109 1 1.0UF 1 1 4.7UF CB76 1 CB126 CB71 2 2 2 2 2 2 2 TITLE: DATE: MAX24310 REV B ENGINEER: 8 7 6 5 A 2 10UF CB48 2 1.0UF 1 1 CB82 1 1 TP7 2 1 B1 2 2 CB90 1 2 1 1 2 3 B2 RB8 10UF 1.0UF C9 1 CB18 V1_8_ANA_F 1 1.0UF 0.02 4 A 2 4 R_SENSE CB72 5 2 1 2 RS- RS+ V1_8_ANA VSENSE_18ANA 2 GND GND 3 1.0UF MAX9610 1.0UF UB7 CB78 50V/V OUT 4 3 12-20-2012 PAGE: 2 5 OF 15 1 7 6 UB9 2 1 15 10UF CB21 SHDN* 11 GND 10 SENSO 1 2 2 3 4 4 5 5 6 6 8 7 7 8 9 9 10 VDDOA 1 B7 D 2 10 2 SET V1_5 SENSO 1 10UF CB30 2 6 RST* 1 3 1 14 OUT4 4.7UF OUT3 IN4 CB89 IN3 5 2 4 J5 V1_5 V1_8_D V2_5 V3_3 1 13 1.0UF OUT2 CB73 IN2 V3_3 3 10UF CB17 12 V1_8_D V2_5 OUT1 10UF CB13 IN1 7 3 V2_5 2 1 4.7UF CB60 2 D 4 10UF CB9 V5_0 5 10UF CB7 8 CONN_10P MAX1793_U2 J6 OUT2 13 14 OUT4 15 RST* 6 1 6 7 8 8 9 9 10 B8 2 10 2 IN4 10UF 5 5 7 VDDOB 1 C 2 OUT3 CB32 4.7UF CB59 2 IN3 SENSO 6 1 IN2 4 4 5 4.7UF 3 2 4 CB88 12 2 2 OUT1 1 3 1.0UF IN1 1 3 1 2 1 C V1_5 UB10 V5_0 V1_5 V1_8_D V2_5 V3_3 CB77 2.5V 7 SHDN* CONN_10P SET 11 GND 10 J7 4 4 5 6 7 8 8 2 7 10 4 0.02 1 J8 V1_5 V1_8_D V2_5 V3_3 SENSO R5 1 CB132 CONN_10P 1 3 B 2 2 1 2 4 R_SENSE 10 4.7UF 8 10 10UF SENSO 1 1 2 2 3 3 4 4 5 5 6 6 7 7 8 8 9 9 10 VDDOD 1 B9 2 10 A 2 2 2 CONN_10P 8 9 2 2 10 1.0UF CB56 9 C14 9 1 5 6 7 9 B10 1 3 5 7 VDDOC 1 4.7UF 2 3 6 CB133 1 2 6 1.0UF 1 5 RS- V3_3 GND GND RS+ V1_5 V1_8_D V2_5 SENSO VSENSE_SENSO 4 5 1 MAX9610 J9 3 2 4 CB142 50V/V OUT U2 2 3 1.0UF 1.5V B 1 3 1 MAX1793_U2 1 CB143 V1_5 V1_8_D V2_5 V3_3 A CONN_10P TITLE: DATE: MAX24310 REV B ENGINEER: 8 7 6 5 4 3 12-20-2012 PAGE: 2 6 OF 15 1 8 7 6 5 4 3 2 1 2.7V V3_3 UB3 Y4 IN1 OUT1 12 OUT2 13 4 IN3 OUT3 14 5 IN4 OUT4 15 RST* 6 7 SHDN* 1 V3_3 10UF IN2 CB38 3 RB29 1 2 10.0K 2 2 CB10 4.7UF 1 2 SET 11 GND 10 ESDI ESDO ESCLK ECS_NJ 5 SI 8DIP VCC 8 2 SO WP* 3 6 SCK HOLD* 7 1 CS* GND 4 E_WP E_HOLD D 1.00K D RB32 V1_8_D RB31 1.00K V5_0 AT25160A_U SOCKET FOR 8 PIN DIP MAX1793_U2 C 3 1.8V ECS_N UB4 2 OUT2 13 4 IN3 OUT3 14 5 IN4 OUT4 15 RST* 6 V3_3 1 2 1 10UF CB35 4.7UF CB14 2 SET 11 GND 10 2.7V CB75 SHDN* U3 V3_3 B MAX1793_U2 1 RB28 2 10.0K 1.8V ESDI ESDO ESCLK 2 7 1 IN2 5 SI VCC 8 2 SO WP* 3 6 SCK HOLD* 7 1 CS* GND 4 4.7UF 3 CB80 12 2 OUT1 1 IN1 1 V1_8_ANA 2 I342 JMP8 4.7UF C B E_WP E_HOLD AT25160A_U 8 PIN SOIC A A 1 4.7UF 2 CB33 1 4.7UF CB22 2 2 CB6 4.7UF 1 V1_8_DIG TITLE: DATE: MAX24310 REV B ENGINEER: 8 7 6 5 4 3 12-20-2012 PAGE: 2 7 OF 15 1 5 4 3 2 1 V5_0 UB12 3 4 4 5 5 6 6 7 7 8 8 9 1 9 10 UGIO_1 UGIO_2 UGIO_3 UGIO_4 1 1 2 2 RB13 1.00K 3 3 4 4 RB15 1.00K 5 5 6 6 RB16 1.00K 7 7 8 8 RB19 1.00K 9 9 10 V3_3 10 VSENSE_SENSO 50 SENSO PTD5 51 PTB0/MISO2/ADP0 PTD6 52 PTB1/MOSI2/ADP1 PTD7 53 PTB2/SPSCK2/ADP2 PTE0/TXD1 13 37 PTB3/SS2/ADP3 PTE1/RXD1 14 38 PTB4/KBIP4/ADP4 PTE2/TMP1CH0 15 39 PTB5/KBIP5/ADP5 PTE3/TPM1CH1 16 40 PTB6/ADP6 PTE4/MISO1 41 PTB7/ADP7 PTE5/MOSI1 60 PTC0/SCL 61 PTC1/SDA 62 PTC2 PTF0/TPM1CH2 63 PTC3/TXD2 PTF1/TPM1CH3 PTC4 PTF2/TPM1CH4 PTC5/RXD2 PTF3/TPM1CH5 9 PTC6 PTF4/TPM2CH0 3 RESET* PTF5/TPM2CH1 PTA5 U1 V3_3_ANA V3_3_DIG V1_8_ANA V1_8_DIG 34 35 36 VSENSE_33ANA VSENSE_33DIG VSENSE_18ANA VSENSE_18DIG I2C_SCL I2C_SDA VBUSDET PTE6/SPSCK1 PTE7/SS1 2 1 1 4 3 2 MR* 4 GND RESET* 2 V3_3 PTF7 24 USBDP PTG0/KBIP0 23 USBDN PTG1/KBIP1 RST_811* PTG2/KBIP6 2 33.2 RB6 USBDN_A 1 55 PTG4/XTAL 57 PTG5/EXTAL 58 7 2 22 47 46 59 A RB7 2 1 CB25 BKGDMS 1 2 2 3 3 4 4 5 5 6 6 2 V5_0 J2 1 RST* TITLE: 6 5 REV B ENGINEER: 4 3 1.00M DATE: MAX24310 CONN_2x3 8 1 12.0000MHZ X1 1 1 1 2 3 4 B 54 PTG3/KBIP7 10.0K VDD DATDAT+ GND SH 3.3UF SPI1_MISO SPI1_MOSI 19 SPI1_SCK V3_3 20 SPI1_SS* RED 4 UGIO_1 RB12 330 DS2 RED 5 UGIO_2 RB14 330 DS3 6 UGIO_3 RB17 330 DS4 GREEN 7 UGIO_4 RB18 330 DS5 GREEN 8 UGIO USAGE: DRIVE HIGH TO TURN OFF LED 11 INSTALL JUMPER TO PULL PIN LOW REMOVE JUMPER AND INTERNAL 12 PULLUP WILL BIAS TEMPORARILY TRISTATE TO READ PIN 10 ASSIGNMENTS: 26 UGIO_1 = POWER CONSUMPTION UGIO_2 UNASSIGNED 27 UGIO_3 UNASSIGNED UGIO_4 UNASSIGNED 18 VBUSDET 2 5 USB J4 1 C 17 R4 VBUS 2 UART1_TXD UART1_RXD 2 33.2 A VSSOSC USBDP_A 1 VREFL 100K RB5 1 3.08V PTF6 2 1 VCC RB10 3 IRQ/TPMCLK BKGD/MS VSS .1UF C15 BKGDMS 56 MAX811_U 2 1 2 SW1 1 UB11 VSSAD RST* 64 1 2 49 PTD4/ADP11 33 0.1UF CB61 1 48 PTD3/KBIP3/ADP10 MC9S08JM 10.0K R6 B 10UF 0.1UF CB57 2 C12 1 CB29 4.7UF 2 CB31 .47UF 1 VREFH VDD VDDAD 21 44 45 25 2 10UF CB24 2 .1UF PTD2/KBIP2/ACMPO PTA3 PTA4 D 4.096V PTA2 32 CONN_10P 3 V3_3_OSC 31 J14 GND VSENSE_33OSC 30 C IC8 43 PTA1 CONN_10P 8 PTD1/ADP9/ACMP- 29 PROCESSOR PULLS UP MOSI AND MISO 4 42 PTA0 10 1 GNDS 22PF 3 NR IC5 PTD0/ADP8/ACMP+ 28 I2C_SCL I2C_SDA UART1_RXD UART1_TXD OUTS 5 1 2 6 CB27 2 2 IN 2 1 OUTF MAX6126 VUSB33 1 0.1UF 2 C11 ECS_N 7 22PF JMP7 2 J1 SPI1_SS* SPI1_SCK SPI1_MOSI SPI1_MISO CB28 2 10.0K 1 RB2 2 10.0K 1 RB1 D 1 VREFH CB53 V5_0 1 V5_0 1 6 2 7 CB58 0.1UF 8 12-20-2012 PAGE: 2 8 OF 15 1 8 7 6 5 4 3 2 V3_3_OSC_F J53 NOTES: 1. U6 AND UB22 REMOVED, UB22 WIRED ACCROSS TO REMOVE THESE COMPONENTS FROM THE MCLKOSC SIGNAL PATH. THE ADDITIVE JITTER OF THESE COMPONENTS WAS TOO HIGH. 2. OSCILLATOR COMPONENT SITE Y6 IS NOT AVAILABLE FOR USE. 3. SMB CONNECTOR INPUTS J33 AND J41 ARE NOT AVAILABLE FOR USE. CONN_6P_U 2 3 3 4 4 5 5 6 6 V3_3_OSC_F RB40 3 10 3.3UF 10 5 NC5 OUT- 8 4 GND NC6 6 2 C53 2 3 U6 DNP R51 30.0 2 VCC 2 IN- OUT1+ 10 4 PD1 OUT1- 9 5 PD0 OUT0+ 7 3 GND OUT0- 6 JMP24 DIFFOSC_ED2 GND OUTN OUT 4 DIFFOSC_ED1 DIFFOSC_ED2 0.1UF 2 CB149 1 ED1 ED2 1 A MAX9175 11 1 .001UF 3 2 JUMPER WIRE 2 Y6 DNP VCC 2 CB148 1 .1UF CB146 V3_3_OSC_F 8 IN+ JMP27 6 2 1 2 1 5 1 V3_3_OSC_F C47 .001UF 1 R42 EX_MCLKOSC- 1 2 3X5MM 5 TITLE: DATE: MAX24310 REV B 12-20-2012 OSC_XO ENGINEER: 5X7MM DIFF OUT 7 B 3 3 8 RF_OUT 3.3UF DIFFOSC_ED1 49.9 R41 21 1 1 3.3UF C50 JMP26 A 2 2 2 EX_MCLKOSC+ 12 VCC GND JMP23 2 2 OSC_TCXO NC 1 C46 12 C51 1 J33 2 .1UF R52 30.0 C54 3 1 RF_OUT 49.9 GND J41 4 MCLKOSCNEG 1 0.1UF 4 VS Y7 1 C V3_3_OSC_F VC 2 C60 1 .01UF 2 CB156 1 0.1UF C59 2 OUT+ V3_3_OSC_F JMP25 1 MCLKOSCPOS 0.0 MAX9110 5X7MM .01UF NC3 3 C58 2 B CB166 C52 7 OSC_TCXO 1 2 1 100 8 9 VCC RB35 7 9 DIN 3 1 7 DNP 2 8 5 UB22 Y8 2 .01UF 1 6 6 5 2 CONN_10P 2 CB167 1 0.1UF 2 C61 1 .01UF CB157 2 4 4 DNP OSC_MC853X4 NO-POP, W/ HEADER 2 10.0K 0.0 3 2 RB41 RF_OUT 1 3 DNP GND 1 1 1 R50 2 JUMPER WIRE J44 1 6 7 5 SUPPLY_V C 8 D 1 Y9 2 CB169 3.3UF 1 2 CB168 .01UF 1 0.1UF C62 2 2 CB159 .01UF 1 2 1 2 C57 1 2 .1UF CB151 JMP28 10.0K J46 CB153 1 1 1 2 .001UF 1 2 D 1 1 6 5 4 3 PAGE: 2 9 OF 15 1 7 6 5 JMP12 1 2 R22 1 1 IC1POS 2 0.0 RB34 1 0.1UF 2 1 1 2 J54 CONN_6P_U 1 1 2 2 3 3 4 4 5 5 6 6 C IC1NEG SINGLE ENDED: INSTALL JMP12, J54.1+3 DNI JMP14, JMP13 DIFFERENTIAL: INSTALL JMP14, JMP13 DNI JMP12, J54 R30 1 IC2POS 2 1 2 2 100 2 CB136 1 0.0 CB145 R32 1 0.1UF 1 2 1 1 2 RB37 100 JMP18 JMP17 IC2NEG 2 J30 2 C JMP19 1 1 0.0 0.1UF J27 D JMP14 2 1 JMP13 R20 C16 J21 1 2 1 2 1 J23 3 2 C18 D 4 1 8 0.0 0.1UF J31 CONN_6P_U B 1 1 2 2 3 3 4 4 5 5 6 6 SINGLE ENDED: INSTALL JMP19, J31.1+3 DNI JMP17, JMP18 DIFFERENTIAL: INSTALL JMP17, JMP18 DNI JMP19, J31 B V3_3 1 0.1UF 2 A CB64 1 0.1UF 2 C24 A TITLE: DATE: MAX24310 REV B ENGINEER: 8 7 6 5 4 3 12-20-2012 PAGE: 2 10 OF 15 1 8 7 6 R63 OC1NEG 2 2 2 2 0.0 2 OC6POS J18 2 1 OC7NEG J15 2 2 1 OC7POS J16 2 1 1 1 1 1 J28 1 NOTES: 1. THE TERMINATION NETWORKS FOR OC1P/N THROUGH OC8P/N ARE CONFIGURED AS DC-COUPLED DIFFERENTIAL CML. 2. THE TERMATION NETWORKS FOR OC9P/N AND OC10P/N ARE CONFIGURED AS DUAL SINGLE-ENDED CMOS D R48 1 2 J49 0.0 R76 1 1 J32 0.0 0.0 R12 2 1 R31 1 R75 1 1 0.0 0.0 0.0 1 2 R74 1 2 R33 1 0.0 1 2 R66 2 2 R11 1 0.0 OC3POS OC6NEG J17 0.0 R65 OC3NEG 1 R13 1 3 R73 1 0.0 R64 OC1POS 4 R14 1 0.0 D 5 R49 1 2 0.0 0.0 0.0 0.0 R67 R7 R77 R37 J50 C C OC2POS 2 1 2 0.0 R68 OC2NEG 2 2 2 0.0 1 1 2 0.0 2 2 0.0 1 J20 1 1 1 1 1 J47 J40 R38 OC10NEG 0.0 1 0.0 R82 1 B R39 2 30.0 R18 1 J48 0.0 OC10POS 0.0 R72 OC5NEG A J22 1 R46 2 R81 1 1 J37 0.0 30.0 1 1 R47 2 OC9POS J13 1 J38 0.0 R80 1 R21 1 2 30.0 1 1 R36 1 OC9NEG J12 0.0 R71 2 2 1 0.0 R79 1 2 2 0.0 R9 1 0.0 OC5POS OC8NEG J11 0.0 R70 1 R78 1 R10 1 2 2 0.0 B OC4POS OC8POS J10 0.0 R69 2 1 R8 1 0.0 OC4NEG 1 0.0 2 30.0 A J39 0.0 TITLE: DATE: MAX24310 REV B ENGINEER: 8 7 6 5 4 3 12-20-2012 PAGE: 2 11 OF 15 1 8 7 6 5 4 3 2 1 V3_3_PA C49 5 REFIN 4 2 1 10.0K 1 CB158 0.1UF 1 1 C 2 2 R57 49.9 1 2 1 J52 JMP11 0.0 2 1 49.9 R56 1 2 R58 0.0 1 GND_PA GND_TP7 1 1 CB163 0.1UF 2 2 CB164 0.1UF CB165 0.1UF 2 1 GND_PA 2 1 C65 4.7UF 0.1UF C37 I261 2 2 CB154 0.1UF GND_PA 2 JMP9 TP11 2 TP12 1 C63 4.7UF 1 V1_5_PA R53 JMP32 1 1 FB4 2 2 CB155 0.1UF 68UF 1 1 GND_PA 2 1 FB2 B D GND_PA R54 1 CB161 DB6 2 0.1UF 2 PGOOD 2 C32 2 7 10.0K 3 VCC SHDN* 2 REFOUT 1 1 JMP29 2 5 3 1 TP10 0.1UF C33 1 4.7UF C34 0.1UF C31 2 2 FB3 2 1 1 V5_0 1 TP9 10 6 4 2 R45 1 V1_5_PA FB1 J51 V5_0_PA V3_3_PA V3_3 2 1 GND_PA 2 R55 DIFFERENTIAL PROTO AREA 1 PGND EP AGND MAX1510 GND_PA GND_PA V1_5 OUTS 1 GND_PA JMP31 GND_PA 6 8 11 3 IN 2 JMP30 GND_PA OUT 1 1 2 CB152 4.7UF 1 100 R44 12 DNP R43 J45 2 1 1 C55 J42 V3_3_PA 3 4 GND_PA 9 RB42 2 0.0 TP8 CONN_6P_U DNP 2 2 C56 1 5 6 C AC 50OHM TO 3.3V GND_PA 1 0.1UF 6 4 2 GND_PA J43 V1.5/2VTT V3_3_PA CB162 5 3 1 DNP 2 1 R40 49.9 R35 R34 1.5V UB23 J36 2 49.9 1 1 3 4 C48 J34 CONN_6P_U V3_3_PA GND_PA CB160 4.7UF V1_5_PA 1 5 6 D AC 100 OHM J35 B GND_PA POWER SIGNALS ON THIS PAGE HAVE THE PA SUFFIX AND CONNECT TO MAIN SUPPLY USING FERRITE BEAD THIS ISOLATES THE PROTOTYPE AREA FROM THE MAIN BOARD GND_PA 50 OHM TO 0.75V 1 4.7UF C40 2 CB131 0.1UF 2 1 SING_DIF_3.3V V5_0_PA UB21 TP6 1 J29 0.0 GND_PA GND_PA GND_PA GND_PA GND_PA 7 6 3 14 OUT3 IN3 4 15 OUT4 IN4 5 6 RST* SHDN* 7 GND_PA 1 2 IN2 A 11 SET 10 GND PLUGINS. CABLE FROM SMB TO THIS PAGE FOR ACTIVE TERMINATION OR 100OHM DIFFERENTIAL TITLE: 5 DATE: MAX24310 MAX1793_U2 4 REV B ENGINEER: 3.3V DIFFERENTIAL TO SINGLE ENDED 8 IN1 OUT2 4.7UF 1 7 GND OUT1 13 CB141 2 10.0K 12 1 1 RB39 3 2 CB137 8 2 R28 R27 MAX9111 VCC 10UF 2 1 49.9 CB112 1 1 UB20 2 GND_PA J24 GND_PA R26 10.0K 1 R29 49.9 1 A 2 CB113 J25 3 12-20-2012 PAGE: 2 12 OF 15 1 8 7 6 2 2 1 STATUS STATUS AT RESET AUTO CONFIGURE IF GPIO3 IS HIGH SOURCE SWITCHING CONTROL INPUT D UB164 330 2 RB21 2 1 11 3 332 0.0 1 RB20 1 V3_3 GPIO1: GPIO2: GPIO3: GPIO4: 3 NC7SZ86_U BUFFER R15 GPIO1 4 GPIO1_HDR GND=GND D 5 DS6 JMP3 2 RED GPIO2_HDR GND=GND NC7SZ86_U BUFFER R16 C 1 2 1 C UB154 2 GPIO2 2 1 11 3 332 RB22 330 2 V3_3 RB23 0.0 DS7 JMP4 J19 2 RED GPIO3_HDR GND=GND NC7SZ86_U BUFFER R17 GPIO3 1 2 1 UB184 1 1 2 2 3 3 4 4 5 5 6 6 7 7 8 8 9 9 10 2 B GPIO1_HDR GPIO2_HDR GPIO3_HDR GPIO4_HDR 10 B 2 1 CONN_10P 11 3 332 RB25 330 2 V3_3 RB24 0.0 DS8 JMP5 2 RED GPIO4_HDR GND=GND NC7SZ86_U BUFFER R19 1 2 1 UB174 2 GPIO4 332 RB26 330 3 A 1 1 V3_3 2 A 2 RB27 0.0 V3_3 DS9 JMP6 1 .1UF TITLE: DATE: MAX24310 2 CB23 1 .1UF 2 CB83 1 2 CB40 .1UF 1 .1UF 2 CB69 1 .1UF 2 CB70 1 .1UF 2 CB66 1 .1UF CB67 2 2 CB68 .1UF 1 2 RED REV B ENGINEER: 8 7 6 5 4 3 12-20-2012 PAGE: 2 13 OF 15 1 2 2 2 2 2 TP.VDD33 TP.V3_3_ANA_F TP.VDD_DIG_18 TP.V1_8_ANA_F TP.VDDOA TP.VDDOB TP.VDDOC TP.VDDOD VSS_APLL2 VSS_APLL2 VSS_XO VSS_OC VSS_APLL1 VSS_APLL1 VDD_33 0.1UF 0.1UF CB95 VDDOA VDDOB VDDOC VDDOD 4 4 4 TESTPOINTS FOR POWER. 2PIN JMP USED TO ENSURE GND IS CLOSE 3 HB7 HB2 4 HB3 HB5 HB10 HB1 4 4 MAX24310 HB8 4 ENGINEER: 2 4 4 TITLE: HB4 HB11 HB6 4 REV B C42 VDDOA VDDOB VDDOC VDDOD CB43 CB45 CB52 CB51 CB41 0.1UF 0.1UF 0.1UF 0.1UF V3_3_OSC 2 2 2 2 1 1 1 1 V1_8_ANA V1_8_DIG V3_3_ANA V3_3_DIG DB4 C41 C20 C22 V1_8_ANA_F CB49 0.1UF 0.1UF 0.1UF V1_8_ANA C43 C38 C29 C19 VDD_DIG_18 0.1UF 0.1UF DB1 C30 CB117 V3_3_ANA_F CB47 0.1UF 0.1UF CB42 0.1UF VSENSE_33OSC SENSO VSENSE_SENSO CB39 VSENSE_33ANA CB50 VSENSE_33DIG CB44 VSENSE_18ANA CB37 VSENSE_18DIG V1_8_ANA_F 3 C36 C44 C26 C35 C45 C23 C39 VDD33 VDDOA VDDOB VDDOC VDDOD VDD_DIG_18 V3_3_ANA_F VDD33 4 C21 C27 V1_8_ANA_F VDD_DIG_18 V3_3_ANA_F VDD33 CB128 0.1UF CB127 0.1UF 0.1UF CB98 CB130 0.1UF CB119 0.1UF CB106 0.1UF CB94 CB108 0.1UF CB116 0.1UF CB111 0.1UF CB123 0.1UF CB104 0.1UF VDD_XO_18 VDD_XO_33 VDD_OC_18 VDD_DIG_18 VDD_DIG_18 VDD_18 VDDO18A VDDO18B VDDO18C VDDO18D VDDOA VDDOB VDDOC VDDOD CB110 0.1UF VDD_APLL2_33 CB124 0.1UF VDD_APLL1_33 CB102 0.1UF VDD_APLL2_18 D7 E6 E4 E7 E3 G5 G6 G3 E5 D4 D6 C9 H6 H4 C1 D8 G8 G2 D2 5 1 1 1 1 1 5 2 6 1 VSUB VSSOD VSSOC VSSOC VSSOB VSSOB VSSOA VSS_DIG VSS_DIG U5 2 7 6 2 8 7 1 A CB120 0.1UF VDD_APLL1_18 C CB107 0.1UF D 1 D3 D1 J4 G1 J6 G9 D9 D5 F5 G7 G4 F7 F6 F4 F3 B CB103 0.1UF 8 2 1 V3_3_DIG V3_3_ANA V3_3_ANA V3_3_DIG DB5 DB2 V1_8_DIG D LEVEL PROTECTION FILTERING FOR A/D AT MICRO C B MAX24310 3.3UF CAPACITORS 0402, TOP SIDE OF PCB 4 A HB9 4 DATE: PAGE: 12-20-2012 1 14 OF 15 8 7 6 5 4 3 2 1 D D OSCILLATOR DAUGHTER CARD 1 3.3UF 2 C6 1 .01UF CB1 2 0.1UF 2 2 C3 1 .01UF CB4 1 C2 10UF Y3 OSC_TCXO 6 7 5 SUPPLY_V 2 2 C1 C 3.3UF 1 Y1 1 VOSC TP1 1 2 2 GND 1 RF_OUT 4 VS VC GND C 3 1 RF_OUT R1 30.0 2 CLOCK 5X7MM OSC_MC853X4 1 3.3UF Y2 2 C4 1 .01UF 2 CB2 1 0.1UF C5 2 2 CB3 .01UF 1 WITH 10PIN ADAPTER 1 OSC_TCXO NC VCC 8 B B 4 GND RF_OUT 5 1 R2 30.0 2 3X5MM A A TITLE: DATE: MAX24310 REV B ENGINEER: 8 7 6 5 4 3 12-20-2012 PAGE: 2 15 OF 15 1
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