MAX24188EVKIT#

Data Sheet May 2012 MAX24188 EV KIT Evaluates: MAX24188 General Description The MAX24188 EV Kit is an easy-to-use evaluation kit for the MAX24188 Low-Cost IEEE1588 Time Clock. An on-board high-stability TC-OCXO oscillator is provided to allow evaluation of 1588 performance with a variety of network PDV and impairment scenarios. Also, the board can accept an external oscillator input for testing alternate oscillators. The board provides SMB connectors for three device GPIO signals. Through these connectors clock and 1PPS signals can be input or output to lock the MAX24188 time clock to a master time clock or to lock other 1588 components to the MAX24188. Typically the board is controlled by EV kit software running on a Windows PC through the USB interface. The board also has SPI and JTAG headers through which the MAX24188 can be controlled by a processor on another board as needed. Features ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ ♦ Demo Kit Contents GPIO SMB Connectors to Input or Output Clock Signals and 1PPS Signals Onboard TC-OCXO Provides Stable Reference for High-Quality Timing over IEEE1588 Connectors and Component Sites for Alternate Oscillators as Needed Included Universal 5V Power Supply Jumpers to Configure Reset State of MAX24188, GPIO Termination, and More LEDs for Power Supplies Valid and Port Status Soldered MAX24188 for Best Signal Integrity Easy-to-Read Silkscreen Labels Identify the Signals Associated with All Connectors, Jumpers, and LEDs Windows®-Based Evaluation Software Provides Easy Configuration and Monitoring of the MAX241888 Device Evaluation Software Calls MAX24188 HAL Software and Structure is Similar to HAL Software Minimum System Requirements ♦ MAX24188 Board ♦ PC Running Windows XP or later ♦ Power Supply ♦ Available USB Port ♦ USB Cable Ordering Information appears at end of data sheet. 1 ________________________________________________________________________________ MAX24188 EV KIT Contents 1. Board Floorplan .................................................................................................................................................... 4 2. Connections to the Board ..................................................................................................................................... 5 2.1 Power-Supply Connection ........................................................................................................................... 5 2.2 USB Connection .......................................................................................................................................... 5 2.3 Example Setup ............................................................................................................................................. 5 3. Installing the Software .......................................................................................................................................... 5 3.1 Troubleshooting Software Installation.......................................................................................................... 5 4. Running the Software ........................................................................................................................................... 6 5. Software User Interface ........................................................................................................................................ 7 5.1 Status Display .............................................................................................................................................. 7 5.2 Configuration Menu and Command Prompt ................................................................................................ 8 5.2.1 Navigating Menus and Changing Settings............................................................................................... 8 5.2.2 Configuring the Device............................................................................................................................. 8 5.2.3 Other Commands ..................................................................................................................................... 8 5.3 Configuration Menu Detailed Descriptions .................................................................................................. 8 6. Jumpers, Connectors and LEDs......................................................................................................................... 14 7. Component List .................................................................................................................................................. 17 8. Schematics ......................................................................................................................................................... 19 9. Ordering Information ........................................................................................................................................... 19 10. Revision History ............................................................................................................................................. 19 2 ________________________________________________________________________________ MAX24188 EV KIT List of Figures Figure 1. MAX24188 EV Kit Board Floorplan .............................................................................................................. 4 Figure 2. Example Setup ............................................................................................................................................. 5 Figure 3. User Interface Main Screen .......................................................................................................................... 7 List of Tables Table 1. Status Display Fields ..................................................................................................................................... 7 Table 12. MAIN Menu .................................................................................................................................................. 9 Table 13. CONFIG SCRIPTING Menu ........................................................................................................................ 9 Table 14. GPIO PINS Menu ........................................................................................................................................ 9 Table 16. 1588 TIME ENGINE Menu .......................................................................................................................... 9 Table 17. 1588 EVENT GENERATORS Menu ......................................................................................................... 11 Table 18. PEG1/PEG2 COMMANDS Submenu........................................................................................................ 11 Table 19. 1588 TIMESTAMPERS Menu ................................................................................................................... 11 Table 27. LOCK TO PPS Menu ................................................................................................................................. 12 Table 28. TEST Menu ................................................................................................................................................ 13 Table 1. Power and Reset Components .................................................................................................................... 14 Table 2. MAX24188 REFCLK Jumpers and Connectors .......................................................................................... 14 Table 3. MAX24188 Pin Configuration Jumpers ....................................................................................................... 14 Table 5. MAX24188 GPIO1 Jumpers and Connectors.............................................................................................. 15 Table 6. MAX24188 GPIO2 Jumpers and Connectors.............................................................................................. 15 Table 7. MAX24188 GPIO3 Jumpers and Connectors.............................................................................................. 15 Table 8. Processor and Debug Jumpers and Connectors ........................................................................................ 15 3 ________________________________________________________________________________ MAX24188 EV KIT 1. Board Floorplan When the board is oriented as shown in Figure 1, The 5V power supply and USB cable included with the kit are connected to jacks J1 and J2 at the top of the board. The board ships with a TCXO mounted in the Y3 oscillator position and a 25MHz XO in the Y1 position. See section 6 for detailed descriptions of the board’s jumpers, connectors and LEDs. The same PCB is also used for the MAX24288 EV kit, and many components needed for the MAX24288 EV kit are not populated for the MAX24188 EV kit including U5, U7, J29 and J31. Pwr Jack USB Jack Y3 OSC Processor Y2 OSC Y1 OSC MAX 24188 MAX24188 Config Jumpers Figure 1. MAX24188 EV Kit Board Floorplan 4 ________________________________________________________________________________ MAX24188 EV KIT 2. Connections to the Board 2.1 Power-Supply Connection The board is powered through connector J1 using the provided AC wall-plug 5V power supply. LED DS1 illuminates to indicate that the board is powered. 2.2 USB Connection The MAX24188 EV kit software application communicates with the EV kit board through USB connector J2. 2.3 Example Setup 1588 Master or Grandmaster CPU Running 1588 Software Enet Network (switches, routers) Enet USB Timestamper Clock Signal to Timestamper TS locked to ‘188 Clock Master Clock or 1PPS Signal Slave Clock or 1PPS Signal Time Interval Analyzer SW Controls MAX24188 Time Clock ‘188 MAX24188 EV Kit Figure 2. Example Setup 3. Installing the Software Important Note: Do not connect the board to the PC until after installing the software. The device driver for the USB microcontroller will not be installed correctly. Follow these steps to install the MAX24188 EV Kit software: 1. To install the software, run max24188evk.exe. The latest version of the EV Kit software can be downloaded from the Microsemi website or requested from Microsemi timing products technical support. 2. In the window that indicates the publisher could not be verified, click Run. 3. Follow the prompts in the MAX24188 Eval Kit setup wizard, For a default installation, click Next three times. 4. Connect the power cord to the J1 connector on the EV Kit board. 5. Connect a USB cable from a USB jack on the PC to the J2 connector on the EV Kit board. 6. In the notification area, Windows will indicate “Installing device driver” and then indicate “Freescale CDC Device (COM6) Device driver software installed successfully.” The text “COM6” indicates the virtual COM port number assigned to the board. This number varies from system to system. Write down the assigned number to use when running the EV Kit software. If Windows does not show the messages above then verify that the board is powered and is connected to the PC. If the board was already connected to the PC before installing the software then see follow the troubleshooting steps in section 3.1. 3.1 Troubleshooting Software Installation If the board was connected to the PC before installing the software or if the EV kit software does not list the board’s COM port number as an option, then follow these steps: 1. In Windows, go to the Device Manager. In recent versions of Windows this is done by going to Control Panel and double-clicking System. Then in the upper-left corner click Device Manager. 5 ________________________________________________________________________________ MAX24188 EV KIT 2. In the Device Manager window, under Other devices, right-click on Unknown device and select Uninstall. In the Confirm Device Uninstall pop-up click OK. 3. In Control Panel double-click Programs and Features. 4. Right-click on MAX24188 Eval Kit and select Uninstall. 5. Disconnect power and USB cables from the EV Kit board. 6. Follow the steps in section 3. 4. Running the Software To run the software, double-click on the MAX24188 Eval Kit shortcut on the desktop, or in the Windows Start menu, select All Programs  Microsemi  MAX24188 Eval Kit. At the prompt enter the COM port number assigned to the board in step 6 in section 3. The software then displays its main menu, as shown in Figure 2. To start communication with the MAX24188 on the EV kit board, type 1 then Enter to create the MAX24188 HAL. If the software and the USB device driver have been installed correctly then regular screen updates begin, the TE SEC field increments once per second, and TE NS fields displays ever-changing values. If the software exits unexpectedly then run the software again and specify a different COM port number. If none of the listed COM port numbers is correct then follow the troubleshooting steps in section 3.1. 6 ________________________________________________________________________________ MAX24188 EV KIT 5. Software User Interface Configuration Menu MAIN MENU 1> CREATE MAX24188 HAL 2> CONFIG SCRIPTING 3> GPIO PINS 4> 1588 TIME ENGINE 5> 1588 EVENT GENERATORS 6> 1588 TIMESTAMPERS 7> 1588 LOCK TO PPS 8> TEST FUNC> MENU> MENU> MENU> MENU> MENU> MENU> MENU> Command Prompt >_ --------------------------------------------------------------------------MSG: c=clr counts, p=previous, q=quit, s=start/stop status polling COM6: 115200 TE SEC 827 TE NS 237481562 ID 0X0EE0 TS1 SEC 0 TS1 NS 0 TS1EDGE NONE – OFF TS1 CNT 0 TS2 SEC 0 TS2 NS 0 TS2EDGE NONE – OFF TS2 CNT 0 TS3 SEC 0 TS3 NS 0 TS3EDGE NONE – OFF TS3 CNT 0 DPL LOS ON STATE OFF ERR NS 0 GPIO 0X06 DPLL BW 0 DF 0 INTEG 0 FREQ 0 Status Display Figure 3. User Interface Main Screen 5.1 Status Display The status display area (see the bottom of Figure 2) shows the latest data polled from the device. To start software polling and updating of these fields, select CREATE MAX24188 HAL in the main menu. To start or stop polling, use the s command at the command prompt. Table 1 lists and describes the status display fields. Table 1. Status Display Fields Row 1 1 1 2 2 2 2 3 Field TE SEC TE NS ID TS1 SEC TS1 NS TS1EDGE TS1 CNT TS2 SEC Description Time engine seconds field Time engine nanosecond field Value read from the MAX24188 ID register Timestamper 1, timestamp seconds field Timestamper 1, timestamp nanoseconds field Timestamper 1, timestamp edge type, 0=falling, 1=rising Count of timestamps done by timestamper 1 since HAL started or last c command. Timestamper 2, timestamp seconds field 7 ________________________________________________________________________________ MAX24188 EV KIT Row 3 3 3 4 4 4 4 5 5 5 5 6 6 6 6 5.2 Field TS2 NS TS2EDGE TS2 CNT TS3 SEC TS3 NS TS3EDGE TS3 CNT DPL LOS STATE ERR NS GPIO DPLL BW DF INTEG FREQ Description Timestamper 2, timestamp nanoseconds field Timestamper 2, timestamp edge type, 0=falling, 1=rising Timestamper 2, count of timestamps done since HAL started or last c command Timestamper 3, timestamp seconds field Timestamper 3, timestamp nanoseconds field Timestamper 3, timestamp edge type, 0=falling, 1=rising Timestamper 3, count of timestamps done since HAL started or last c command. Hardware/Software DPLL loss of signal Hardware/Software DPLL state Hardware/Software DPLL time error in nanoseconds MAX24188 GPIO status register (GPIOSR) bits 6:0 Hardware/Software DPLL bandwidth Hardware/Software DPLL damping factor Hardware/Software DPLL integral path control Hardware/Software DPLL frequency control Configuration Menu and Command Prompt 5.2.1 Navigating Menus and Changing Settings Figure 3 shows the main screen of the MAX24188 software. In the upper half of the screen the command menu has two columns. The left-hand column shows numbered command/menu options. The right-hand column indicates what happens when an option is chosen. FUNC> indicates that a function is executed, LIST> indicates a list of choices will be presented, and MENU> indicates that the user will be taken to a submenu. Data types such as UINT32> or STR> indicate that a value with the specified data type can be entered. UINT32>, for example, means a 32-bit unsigned integer. STR> means text string. To change the device configuration, the user types a number at the command prompt followed by the Enter key. If the option selected has a data type in the right-hand column, such as UINT32> then the cursor moves to the right of the data type. The user then enters the desired value followed by the Enter key. The cursor then moves back to the command prompt area. If the option selected has LIST> in the right-hand column, then the cursor moves to the right of the LIST> text and a list of options is shown in an additional column on the right. The user then enters the option number from the list followed by the Enter key. The value next to LIST> then changes to the option selected, and the cursor moves back to the command prompt area. 5.2.2 Configuring the Device All menus of the software are designed to have a two-step configuration process: 1. Configure the relevant values using data-type or LIST> menu options. 2. Configure the HAL or the device using a FUNC> menu option. For example, in the GPIO PINS menu, some or all of the parameters in the menu are configured and then CONFIG GPIO is selected to write MAX24188 device registers. 5.2.3 Other Commands In addition to menu item numbers, the following commands are also valid at the command prompt: c – clear counts in status area p – return to previous menu (when in a submenu) q – quit the program s – stop/start status polling 5.3 Configuration Menu Detailed Descriptions 8 ________________________________________________________________________________ MAX24188 EV KIT Table 2. MAIN Menu Name CREATE MAX24188 HAL CONFIG SCRIPTING GPIO PINS 1588 TIME ENGINE 1588 EVENT GENERATORS 1588 TIMESTAMPERS 1588 LOCK TO PPS TEST Description This function creates the MAX24188 HAL and starts polling device status. The three MAX24188* fields below must be set before this function is executed. Opens the CONFIG SCRIPTING menu. See Table 13. Opens the GPIO PINS menu. See Table 14. Opens the 1588 TIME ENGINE menu. See Table 16. Opens the 1588 EVENT GENERATORS menu. See Table 17. Opens the 1588 TIMESTAMPERS menu. See Table 19. Opens the 1588 LOCK TO PPS menu. See Table 27. Opens the TEST menu. See Table 28. Table 3. CONFIG SCRIPTING Menu Name READ CONFIGURATION WRITE CONFIGURATION READ CONFIG FILE NAME WRITE CONFIG FILE NAME Description Function reads configuration information from the file specified by the READ CONFIG FILE NAME parameter below. Function writes configuration information to the file specified by the WRITE CONFIG FILE NAME parameter below. The file name for the READ CONFIGURATION function above. The file extension is .cfg. The file name for the WRITE CONFIGURATION function above. The file extension is .cfg. Table 4. GPIO PINS Menu Name CONFIG GPIO GPIO CONFIG SELECT GPOx MODE, GPIOx MODE (9 fields total) Description Function writes GPIO configuration from the fields below to MAX24188 register GPIOCR1 or GPIOCR2 for the pin(s) specified by GPIO CONFIG SELECT below. Specifies one or all of {GPO1, GPO2, GPIO1-7} to be configured by the CONFIG GPIO function above. Specify high-impedance, low, high, and several other options. Other options are pindependent and include: INT = interrupt output EXT CLK = Output the PTP_CLKO signal from the time engine REFCLK PLL 125 MHZ = Output 125MHz from the reference clock PLL RX 125/25 MHZ = Output clock from receive clock recovery PLL; the frequency is specified by GPIO RX PLL CLK MODE in the DATA PATH menu. RX 125/25 MHZ SQUELCH = same as RX 125/25 MHZ above and the output clock signal is squelched when certain receiver conditions occur such as LOS or ALOS LOS or ALOS = Output real-time link status, 1= link up CRS = Output carrier sense status PEG1 = Output signal generated by Programmable Event Generator 1 PEG2 = Output signal generated by Programmable Event Generator 2 See Table 6-4 through Table 6-6 in the MAX24188 data sheet. Note that GPIO4 through GPIO7 are the TXD4 through TXD7 pins, which are not available when the parallel MII interface is configured as GMII. Table 5. 1588 TIME ENGINE Menu Name SET TIME TIME SEC TIME NS SET FREQ OFFSET FREQ OFFSET +/- PPT DO TIME BUILD OUT Description Function writes time from TIME SEC and TIME NS below to the MAX24188 time engine. Specifies the seconds portion of the time for the SET TIME function above. Affects the MAX24188 TIME register field. Specifies the nanoseconds portion of the time for the SET TIME function above. Affects the MAX24188 TIME register field. Function adjusts the MAX24188 PERIOD register from its nominal value of 8.0ns by the amount specified in the FREQ OFFSET field below. Specifies a time engine frequency offset in parts per trillion (PPT). Affects the MAX24188 PERIOD register field. Function adjusts MAX24188 time engine time smoothly. Time is advanced by the amount specified by TBO ADJUSTMENT (below) over a duration specified by TBO DURATION (below). For example, if TBO ADJUSTMENT is 100ns and TBO DURATION is 1s then DO TIME BUILD OUT advances time in the MAX24188 time 9 ________________________________________________________________________________ MAX24188 EV KIT Name TBO DURATION +/- NS TBO ADJUSTMENT +/- NS CONFIG EXT CLK & PTP_CLKO EXT CLK SOURCE EXT CLK ENABLE EXT CLK DIVIDE EXT CLK LIMIT EXT CLK PER NS (16-255) PTP_CLKO DIVIDE (0=NO DIV) PTP_CLKO INVERT Description engine by an extra 100ns, but it does this extra advance at a rate of 100ns/1s=0.1ppm. DO TIME BUILD OUT makes one-time or repeated used of the precise time adjustment feature described in section 6.13.1.3 of the MAX24188 data sheet. Affects register fields PER_ADJ and ADJ_CNT. Specifies the total time duration during which the time is adjusted by the DO TIME BUILD OUT function above. Specifies the total time adjustment desired for the DO TIME BUILD OUT function above. Function configures the MAX24188 external clock and PTP_CLKO output clock features using the settings of the EXT CLK SOURCE through PTP_CLKO INVERT fields below. See MAX24188 data sheet section 6.13.1.4 for more information about the external clock syntonization feature. See MAX24188 data sheet section 6.13.2 for more information about the PTP_CLKO output clock. Specifies the input signal pin for the MAX24188 external clock syntonization feature. Affects register field PTPCR3.EXT_SRC. Enable/disable control for the MAX24188 external clock syntonization feature. Affects register field PTPCR3.EXT_CLK_ENA. Specifies the external clock divider value. Affects register field PTPCR3.EXT_DIV. Specifies the maximum number of nanoseconds to adjust the time engine accumulator period from the nominal value set by the MAX24188 PERIOD register. Affects register field PTPCR3.EXT_LIM. Specifies the period of the external clock after being divided by the EXT CLK DIVIDE value. Affects register field PTPCR3.EXT_PER. Specifies the divide value for the PTP_CLKO signal. PTP_CLKO frequency is 125MHz divided by this value. Affects register field PTPCR2.CLKO_DIV. Invert/non-invert control. Affects register field PTPCR2.CLKO_INV. 10 ________________________________________________________________________________ MAX24188 EV KIT Table 6. 1588 EVENT GENERATORS Menu Name CONFIG PEG PEG CONFIG SELECT PEG1 MODE PEG1 OFFSET NS PEG2 MODE PEG2 OFFSET NS PEG1 COMMANDS PEG2 COMMANDS Description Function configures the MAX24188 programmable event generator(s) (PEGs) using settings from the fields below and the PEG1 COMMMANDS and PEG2 COMMANDS submenus. Specifies one or both of the PEGs to be configured by the CONFIG PEG function above. Allows the user to specify that PEG1 generate one of several common clock frequencies from 0.5Hz through 31.25MHz. If the CUSTOM option is selected then the user can specify a custom PEG command script in the PEG1 COMMANDS submenu. When PEG1 MODE≠CUSTOM then this field specifies an offset from the one-second boundary for the first edge generated by the PEG. If PEG1 OFFSET=0 then PEG1 is configured to generate the first output signal edge when the time engine’s nanosecond field equals 0. If, for example, PEG1 OFFSET=-10 then PEG1 is configured to generate the first output signal edge when the time engine’s nanoseconds field equals 999,999,990 (i.e. 10ns before the nanoseconds field rolls over to 0). Same as PEG1 MODE above but for PEG2. Same as PEG1 OFFSET above but for PEG2. Opens the PEG1 COMMANDS Menu where a custom PEG1 command script can be entered. See Table 18. Same as PEG1 COMMANDS above but for PEG2. Table 7. PEG1/PEG2 COMMANDS Submenu Name CMD RESOLUTION CMD WORD LENGTH CMD WORD 0 – CMD WORD 15 Description Specifies 1ns or 1/256ns resolution for the 16-bit and 32-bit relative time commands written to the PEG command FIFO. Affects register field PEGCR.P1RES for PEG1 and PEGCR.P2RES for PEG2. Specifies the number of words of CMD WOR 0 through CMD WORD 15 below that the software should write to the PEG command FIFO. CMD WORD LENGTH=1 indicates that only CMD WORD 0 should be written. CMD WORD LENGTH=4 indicates that CMD WORD 0 through CMD WORD 3 should be written. Specifies up to 16 entries to be written to the PEG command FIFO. The CMD WORD LENGTH field above specifies the number of entries that are written to the PEG command FIFO. Table 8. 1588 TIMESTAMPERS Menu Name CONFIG TS TS CONFIG SELECT TS1 SOURCE TS1 EDGE TS1 OFFSET NS TS1 DIVIDER 1 TS1 DIVIDER 2 TS2 SOURCE TS2 EDGE TS2 OFFSET NS Description Function configures the MAX24188 timestampers using settings from the fields below and the PACKET TS FIFO ENABLES submenu. Specifies one or all of the timestampers to be configured by the CONFIG TS function above. Specifies the source of the signal to be timestamped by timestamper 1. Affects register field TSCR.TS1SRC_SEL. Specifies whether positive edges, negative edges or both should be timestamped by timestamper 1. Affects register field TSCR.TS1EDGE. Specifies an offset in nanoseconds that software adds to each timestamp generated by the MAX24188. This field allows software to correct for cable delays, signal skews, etc. Specifies the timestamper 1 divider 1 setting. One or both of the TS1 dividers can be used to divide down the frequency of the input signal that goes to timestamper 1 in order to reduce the number of edges that must be timestamped. The input signal frequency is divided by value entered + 1. Affects register field TS1_DIV1. Specifies the timestamper 1 divider 2 setting. Affects register field TSCR.TS2SRC_SEL. Specifies the source of the signal to be timestamped by timestamper 2. Affects register field TSCR.TS2SRC_SEL. Specifies whether positive edges, negative edges or both should be timestamped by timestamper 2. Affects register field TSCR.TS2EDGE. Same as TS1 OFFSET NS above but for timestamper 2. 11 ________________________________________________________________________________ MAX24188 EV KIT Name TS3 SOURCE TS3 EDGE TS3 OFFSET NS Description Specifies the source of the signal to be timestamped by timestamper 3. Affects register field TSCR.TS3SRC_SEL. Specifies whether positive edges, negative edges or both should be timestamped by timestamper 3. Affects register field TSCR.TS3EDGE. Same as TS1 OFFSET NS above but for timestamper 3. Table 9. LOCK TO PPS Menu Name CONFIG LOCK TO PPS PLL MODE Description Function configures the evaluation software using settings from the fields below to work with the MAX24188 hardware to form a hardware/software PLL that locks to an input 1PPS signal. In this PLL, timestamper 1 (TS1) in the MAX24188 timestamps edges of a 1PPS input signal. The edges of this signal are assumed to occur at the exact one-second boundary. Therefore ideally the timestamp nanoseconds field should be 0. The difference between the nanosecond field and zero is the error information used to control the PLL. Note 1: TS1 must be configured to timestamp an input 1PPS signal in the 1588 TIMESTAMPERS Menu (Table 19) before executing the CONFIG LOCK TO PPS function. Note 2: The evaluation software controls the time and/or frequency of the MAX24188 time engine when PLL MODE below is not OFF. Therefore previous settings of time engine values may be overwritten by the evaluation software when the LOCK TO PPS PLL is enabled. Specifies operating mode of the hardware/software PLL. Mode OFF FREERUN FREQ MEASURE FREQ ADJUST TIME ADJUST TIME MEASURE TIME BUILD OUT LOCK HOLDOVER AUTO FREQ LOCK AUTO TIME LOCK EVENTS PER SECOND FREERUN FREQ PPM FREQ RATE OF CHANGE PPM/SEC PLL BANDWIDTH, HZ PLL DAMPING FACTOR Description Disable the PLL Ignore error information from TS1 and clock the time engine at the frequency specified by the FREE RUN FREQ PPM field below. For debug only. These values force the hardware/software PLL into a particular operating state. Ignore error information from TS1 and clock the time engine at a holdover frequency averaged by the evaluation software while the PLL was locked to an input signal. Fully automatic PLL operation with frequency-only locking. When the PLL is locked its output frequency tracks the frequency of the input signal, but time is not adjusted. Therefore the MAX24188 time engine will have a fixed time offset vs. the source of the input signal. Fully automatic PLL operation with time-and-frequency locking. When the PLL is locked the time and frequency of the MAX24188 time engine track the input signal. Specifies the number of edges per second in the input signal timestamped by TS1. For a 1PPS signal this field should be set to 1. Specifies a frequency offset vs. the frequency accuracy of the REFCLK oscillator for when PLL MODE above is set to FREERUN. Specifies the maximum frequency rate of change that the evaluation software can use when locking to an input signal. Specifies the bandwidth of the hardware/software PLL in Hz. Specifies the damping factor of the hardware/software PLL. A typical value is 5. Larger numbers provide more damping, i.e. less peaking at the PLL corner frequency. 12 ________________________________________________________________________________ MAX24188 EV KIT Table 10. TEST Menu Name READ REGISTER WRITE REGISTER REGISTER ACCESS MODE REGISTER ADDRESS HEX REGISTER ADDRESS DEC REGISTER DATA HEX REGISTER DATA DECIMAL READ SFP MODULE INFO Description Function reads the register specified by the REGISTER ADDRESS fields below and displays the value in the REGISTER DATA fields below. Functions writes the data value specified in the register data fields below into the register address specified by the REGISTER ADDRESS fields below. Specifies the register access mode. MAX24188 USER MODE: The registers in Table 7-1 of the MAX24188 data sheet are at addresses 0-31 decimal, and the registers in Table 7-2 of the MAX24188 data sheet are at 32 (decimal) + SPI address. SW PHY0 (MDIO#8): Accesses the registers of PHY0 on the evaluation board’s switch chip. SW PHY1 (MDIO#9): Accesses the registers of PHY1 on the evaluation board’s switch chip. SW MAC (MDIO#A): Accesses the MAC registers of the evaluation board’s switch chip for the port connected to the MAX24188. SFP CFG (I2C#A0): Accesses the SFP module’s internal EEPROM memory. SFP PHY (I2C#AC): Accesses the SFP module’s PHY registers. Specifies the register address in hexadecimal for the READ REGISTER and WRITE REGISTER functions above. When REGISTER ADDRESS DEC below is changed, this field is changed to match. The REGISTER ACCESS MODE field above specifies the register mapping. Specifies the register address in decimal for the READ REGISTER and WRITE REGISTER functions above. When REGISTER ADDRESS HEX above is changed, this field is changed to match. Indicates the data value in hexadecimal from the last time the READ REGISTER function was executed or the last time one of the REGISTER DATA fields was change by the user. Indicates the data value in decimal from the last time the READ REGISTER function was executed or the last time one of the REGISTER DATA fields was change by the user. Functions reads and displays the data from the evaluation board’s SFP module. To end the data display and return to the menu, press the ENTER key. 13 ________________________________________________________________________________ MAX24188 EV KIT 6. Jumpers, Connectors and LEDs Table 11. Power and Reset Components COMPONENT LABEL AND TYPE BASIC SETTING SCHEMATIC PAGE J1 5V jack Connected 4 Power jack for 5V wall adapter (supplied) DS1 DS2 DS3 SW1 5.0V_OK LED 3.3V_OK LED 1.2V_OK LED DUT_RST button On 4 Lit when power is within range for 5V, 3.3V, and 1.2V, respectively Unused 5 Manual reset for entire system DESCRIPTION Table 12. MAX24188 REFCLK Jumpers and Connectors Note: MAX24188 is intolerant of REFCLK signal changes during operation. To make REFCLK signal changes, power down the board, change the jumpers as needed then apply power to the board again. COMPONENT LABEL AND TYPE JP1 Y2OSC / Y3OSC selection 3-pin header J3 OSC_OUT SMB connector SER_TRM 2-pin header J4 J10 J25 EXT_REFCLK SMB connector 50PAR 2-pin header BASIC SETTING Jumper connecting pins 2 and 3 Not monitored Not monitored SCHEMATIC PAGE 7 7 7 Not monitored 7 Not monitored 7 J14 REFCLK 2x3pin header Jumper connecting pins 5 and 6 7 J19 OSC 3.3V POWER 2x3pin header All jumpered 7 DESCRIPTION Drives SMB connector J3 and jumper J14 pin 1. Connect the Y3OSC pin to the center pin to connect the Y3 oscillator output to J3 and J14. Connect the Y2OSC pin to the center pin to connect the Y2 oscillator output to J2 and J14. J3 is driven by a buffer sourced by the center pin of JP1. Install a jumper on J4 to apply 50 ohm parallel termination to J3 External REFCLK oscillator input. Signal goes to J14 pin 1. Jumper J25 to apply 50 ohm parallel termination to J10. Connects 25MHz XO clock or Y2/Y3 clock or external clock to MAX24188 REFCLK pin. Frequency must match the settings of the REF[1:0] jumpers (see Table 3). Connect pins 1 and 2 to select the external clock signal from SMB J10. Connect pins 3 and 4 to select the Y2 or Y3 clock signal from JP1. Connect pins 5 and 6 to select the Y1 clock signal. Connect/disconnect 3.3V power for oscillator components Y1, Y2 and Y3. Connect pins 1 and 2 to power Y3 Connect pins 3 and 4 to power Y2 Connect pins 5 and 6 to power Y1 Note: the silkscreen mistakenly has Y2OSC and Y3OSC labels swapped. Table 13. MAX24188 Pin Configuration Jumpers COMPONENT LABEL AND TYPE BASIC SETTING JP27 JP28 REF[1:0] 3-pin headers JP27: VCC JP28: GND SCHEMATIC PAGE DESCRIPTION 3 MAX24188 RXD[3:2] pins. At reset the values on these pins are latched into the internal REFCLK frequency register. 00=10MHz, 01=12.8MHz, 10=25MHz, 11=125MHz. 14 ________________________________________________________________________________ MAX24188 EV KIT COMPONENT LABEL AND TYPE BASIC SETTING SCHEMATIC PAGE JP12, JP13, JP14, JP15, JP16, JP17, JP18, JP19, JP23, JP24, JP25, JP26, JP29, JP30 Various labels 3-pin header Not Jumpered various DESCRIPTION Not used in MAX24188 EV Kit Table 14. MAX24188 GPIO1 Jumpers and Connectors COMPONENT LABEL AND TYPE BASIC SETTING J18 SMB Connector GPIO1 3-pin header Not jumpered SCHEMATIC PAGE 3 Not jumpered 3 JP6 and JP9 3-pin headers Not jumpered 3 J22 2-pin header Not jumpered 3 J26 2-pin header Not jumpered 3 DS4 LED Off 3 JP5 DESCRIPTION I/O connector for GPIO1. Can be used to bias GPIO1 high or low. To drive a signal from SMB J18 to GPIO1, jumper JP6 2-3 and JP9 2-3. To drive a signal from GPIO1 to SMB J18, jumper JP6 1-2 and JP9 1-2. Install J22 to short the 30 ohm series termination at JP6.2. Install J26 to apply 50 ohm parallel termination to JP9.2 Lit when GPIO1 is high. Table 15. MAX24188 GPIO2 Jumpers and Connectors COMPONENT LABEL AND TYPE BASIC SETTING J16 SMB Connector GPIO1 3-pin header Not jumpered SCHEMATIC PAGE 3 Not jumpered 3 JP7 and JP10 3-pin headers Not jumpered 3 J23 2-pin header Not jumpered 3 J27 2-pin header Not jumpered 3 JP4 DESCRIPTION I/O connector for GPIO2. Can be used to bias GPIO2 high or low. To drive a signal from SMB J16 to GPIO2, jumper JP7 2-3 and JP10 2-3. To drive a signal from GPIO1 to SMB J16, jumper JP7 1-2 and JP10 1-2. Install J23 to short the 30 ohm series termination at JP7.2. Install J27 to apply 50 ohm parallel termination to JP10.2 Table 16. MAX24188 GPIO3 Jumpers and Connectors COMPONENT LABEL AND TYPE BASIC SETTING J17 SMB Connector GPIO1 3-pin header Not jumpered SCHEMATIC PAGE 3 Not jumpered 3 JP3 JP8 and JP11 3-pin headers Not jumpered 3 J24 2-pin header Not jumpered 3 J28 2-pin header Not jumpered 3 DESCRIPTION I/O connector for GPIO3. Can be used to bias GPIO3 high or low. To drive a signal from SMB J17 to GPIO3, jumper JP8 2-3 and JP11 2-3. To drive a signal from GPIO1 to SMB J17, jumper JP8 1-2 and JP11 1-2. Install J24 to short the 30 ohm series termination at JP8.2. Install J28 to apply 50 ohm parallel termination to JP11.2 Table 17. Processor and Debug Jumpers and Connectors COMPONENT LABEL AND TYPE BASIC SETTING SCHEMATIC PAGE J2 (USB) USB jack Connected 8 USB connector, attach to PC with supplied cable J5 PROCESSOR DEBUG 2x3pin header Not Connected 8 BDM connector for use with debug pod DESCRIPTION 15 ________________________________________________________________________________ MAX24188 EV KIT COMPONENT LABEL AND TYPE J9 COM_BCLK 2x3pin header J12 J13 J15 BASIC SETTING SCHEMATIC PAGE DESCRIPTION Not jumpered 5 Used to make a common communication clock. Jumper options allow to short MDC, I2C_CLK and SPI clock. 2x5pin header Jumpered 3-4, 5-6, 7-8, 9-10 5 Not used in MAX24188 EV Kit. 2x5pin header Jumpered 1-2, 3-4, 5-6, 7-8 5 Not used 5 2x7 header J21 2x5 header Not used 5 J11 2-pin header Not used 5 J34 2x5pin header Jumpered 9-10 5 JB1 2x5 header (just below the company logo) Not jumpered 8 Connection points for processor pins to MAX24188 SPI. Disconnect if connecting an external processor. Connection for external processor board SPI bus connection to external board such as Microsemi’s DS31400DK. Place a jumper to connect 5V to J15 pin 2. MAX24188 JTAG header. When not in JTAG mode the JTRST pin should be driven low by connecting pins 9 and 10. Connects to several GPIO on the processor to provide for future board application options. 16 ________________________________________________________________________________ MAX24188 EV KIT 7. Component List DESIGNATION Reference designators shown on next row (C1, …, CB143) QTY 81 DESCRIPTION 0402 CERAM 1uF 10V SUPPLIER TDK PART C1005X5R1A105M C1, C2, C12, C13, C14, C22, C27, CB8, CB10, CB13, CB14, CB21, CB23, CB25, CB28, CB30, CB31, CB34, CB35, CB36, CB37, CB38, CB39, CB40, CB41, CB42, CB45, CB49, CB50, CB51, CB52, CB53, CB54, CB55, CB57, CB58, CB62, CB64, CB66, CB67, CB69, CB70, CB71, CB73, CB74, CB76, CB77, CB79, CB81, CB84, CB86, CB87, CB89, CB91, CB92, CB94, CB95, CB98, CB99, CB100, CB102, CB104, CB106, CB107, CB113, CB115, CB116, CB119, CB121, CB122, CB123, CB124, CB127, CB128, CB129, CB133, CB134, CB135, CB141, CB142, CB143 Reference designators shown on next row (C3, …, CB145) 41 0402 CERAM 0.01uF 16V 10% Panasonic ECJ-0EB1C103K C3, C8, C10, C17, C24, CB3, CB7, CB12, CB26, CB27, CB47, CB59, CB60, CB61, CB63, CB65, CB68, CB72, CB75, CB78, CB80, CB82, CB83, CB85, CB88, CB90, CB93, CB96, CB97, CB101, CB103, CB105, CB108, CB109, CB110, CB111, CB114, CB117, CB118, CB120, CB145 C4, C9, C11, C15, C16, C18, C19, C20, C21, C23, C25, C26, CB1, CB2, CB4, CB5, CB9, CB11, CB15, CB19, CB20, CB24, CB29, CB32, CB33, CB44, CB46, CB56, CB112, CB125, CB130, CB131, CB132, CB139, CB140, CB146 C5, CB18 36 2 0603 CERAM 10uF 6.3V 20% MULTILAYER 0603 CERAM .1uF 16V 20% X7R Panasonic AVX ECJ-1VB0J106M 0603YC104MAT C6, C7 2 0603 CERAM 22pF 25V 5% NPO AVX 06033A220JAT CB17, CB22 CB43, CB48, CB126, CB136, CB137, CB138 2 0603 CERAM 4.7uF 6.3V MULTILAYER UNK ECJ-1VB0J475M 6 CAP CER 3.3UF 4.0V X5R 0402 AMK AMK105BJ335MV-F CB6, CB16, CB144 3 D CASE TANT 470uF 6.3V 20% KEM T491D477M006AS SCHOTTKY DIODE, 1 AMP 40 VOLT International Rectifier 10BQ040 11 LED, GREEN, SMD Panasonic LN1351C DS4, DS15, DS16 3 LED, GREEN, SMD Panasonic LN1351C DS9, DS10 GND_TP1, GND_TP2, GND_TP3, GND_TP4 2 LED, RED, SMD Panasonic LN1251C 4 KEYSTONE 4954 J1 1 STANDARD GROUND CLIP 2.0MM SURFACE MOUNT POWER JACK CUI INC PJ-002AH-SMT J11 1 2 PIN HEADER, .100 CENTERS, VERTICAL Samtec TSW-102-07-T-S J13, J34 4 TERMINAL STRIP, 10 PIN, DUAL ROW, VERT DIG J15 1 HEADER, 14 PIN, DUAL ROW, VERT NOT POPULATED S2012-05-ND HDR-TSW-107-14-T-D Samtec J2 1 TYPE B SINGLE RT ANGLE, BLACK MOL NA J3, J10, J16, J17, J18 6 CONNECTOR, SMB, 50 OHM VERTICAL, 5PIN AMP 413990-1 100 MIL 2 POS JUMPER NA NA Samtec TSW-103-07-T-D DNP DNP NA NA Steward HI1206N101R-00 DB1 DS1, DS2, DS3, J4, J8, J22, J23, J24, J25, J26, J27, J28 1 11 J5, J6, J9, J14, J19 5 JB1 J15, J21 3 JP1, JP3, JP4, JP5, JP6, JP7, JP8, JP9, JP10, JP11, JP12, JP13, JP14, JP15, JP16, JP17, JP18, JP19, JP23, JP24, JP25, JP26, JP27, JP28, JP29, JP30 LB1, LB3, LB4, LB9, LB10, LB11, LB12, LB13, LB14 34 9 TERMINAL STRIP, 6 PIN, DUAL ROW, VERT TERMINAL STRIP, 10 PIN, DUAL ROW, VERT DO NOT POPULATE 100 MIL 3 POS JUMPER FERRITE 3A 100 OHM AT 100 MHZ 1206 SMD 17 ________________________________________________________________________________ MAX24188 EV KIT DESIGNATION QTY DESCRIPTION SUPPLIER PART LB5, LB6, LB7, LB8 4 1uH ±10% 0805 Multilayer Ceramic 400 mA (ok to sub with 445-3156-1-ND) Murata LQM21FN1R0N00D R1, R4, R5, R6, R7, R9, R10, RB5 9 RES 0603 30 Ohm 1/16W Panasonic ERJ-3GEYJ300V R11, R18, R19, R21, R57, RB8, RB3 4 RES 0402 0 OHM 1/10W 5% Panasonic ERJ-2GE0R00X R12, R17, R20, R22, R23, R29, R31, R32, R33, R34, R35, R36, R37, R38, R39, R40, R41, R42, R43, R44, R45, R46, R47, R48, R49, R50, R51, R52, R53, R54, R55, R56 32 RES 0201 30.0 OHM 1/16W 1% Panasonic ERJ-1GEJ300C R13, R14, R25, R26, RB23, RB24, RB25, RB38, RB44, RB45, RB49, RB50, RB51, RB52, RB53, RB54, RB56, RB57, RB63, RB64, RB69, RB71, RB72, RB73, RB77, RB78, RB79, RB80, RB81, RB86, RB87, RES 0402 10.0 KOHM 1/16W 1% Panasonic ERJ-2RKF1002X R16, RB27, RB28, RB29 4 RES 0402 30.0 OHM 1/16W 1% Panasonic ERJ-2RKF30R0X R30, R15 2 RES 0402 100 OHM 1/16W 1% Panasonic ERJ-2RKF1000X R2, R3 2 RES 0603 33.2 Ohm 1/16W 1% Panasonic ERJ-3EKF33R2V RES 0402 1.00 KOHM 1/16W 1% Panasonic ERJ-2RKF1001X R24, R28, R62, R63, RB13, RB15, RB16, RB17, RB18, RB19, RB20, RB21, RB22, RB26, RB39, RB40, RB41, RB42, RB43, RB82 31 18 R27 1 RES 0402 1.40 KOHM 1/16W 1% Panasonic ERJ-2RKF1401X R8 1 RES 0603 1.00M Ohm 1/16W 1% Panasonic ERJ-3EKF1004V RB1, RB4, RB9, RB30, RB31, RB32, RB33, RB34, RB60, RN1 11 RES 0603 1.0K Ohm 1/16W 5% Panasonic ERJ-3GEYJ102V RB14, RB84, RB85, R60 5 RES 0603 330 Ohm 1/16W 5% Panasonic ERJ-3GEYJ331V RB2, RB11, RB35, RB36, RB37 5 RES 0402 49.9 OHM 1/16W 1% Panasonic ERJ-2RKF49R9X RB6, RB10, RB83 3 RES 0603 10K Ohm 1/16W 5% Panasonic ERJ-3GEYJ103V RB65 1 RES 0603 2.49K Ohm 1/16W 1% Panasonic ERJ-3EKF2491V RB7 1 RES 0603 10.0K Ohm 1/16W 1% Panasonic ERJ-3EKF1002V RPB5, RPB6, RPB7, RPB9, RPB13 6 RESISTOR, 4 PACK, 330 OHM 5PCT QUAD 0603 Panasonic EXB-V8V331JX 2 RESISTOR, 4 PACK, 10K OHM 5PCT QUAD 0603 Panasonic EXB-V8V103JX RPB2, RPB3, RPB4 3 RESISTOR, 4 PACK, 33 OHM 5PCT QUAD 0603 Panasonic EXB-V8V330JV RPB8, RPB12 2 RESISTOR, 4 PACK, 4.7K OHM 5PCT QUAD 0603 Panasonic EXB-V8V472JX SW1 TP1,TP2,TP3,TP4,TP5,TP6,TP7,TP8,TP 9,TP10,TP11,TP12,TP13,TP15,TP16,TP 17,TPB1,TPB2,TPB3,TPB4,TPB5,TPB6, TPB7,TPB8,TPB9,TPB10 1 SWITCH MOM 4PIN SINGLE POLE Panasonic EVQPAE04M 26 TESTPOINT, 1 PLATED HOLE, DO NOT STUFF NA NA U1 1 MICROPROCESSOR VOLTAGE MONITOR, 3.08V RESET, 4PIN SOT143 Maxim MAX811TEUS-T U2 1 VOLTAGE MONITOR 5, 3.3, 2.5, ADJ Maxim MAX6709AUB+ HIGH SPEED BUFFER FAIRCHILD NC7SZ86 FREESCALE MC9S08JM32CLH-ND REALTEK RTL8363C RPB10, RPB11 UB3,UB4,UB5,UB6,UB9,UB10,UB11,UB 12,UB13,UB14,UB15,UB16,UB19,UB20 14 U4 1 IC, HCS08 8-BIT MICROCONTROLLER, 32K FLASH, 2K RAM, 2 UART, 2 SPI, I2C, USB, -40 TO 85C, 64 PIN LQFP U5 1 RTL8363 PHY U6 1 MAX24188 QFN 8X8 MICROSEMI MAX24188ETK+ U7 1 SFP host / receptacle PARTS_KIT SFP_HOST-TYCO 18 ________________________________________________________________________________ MAX24188 EV KIT DESIGNATION QTY U8 1 DESCRIPTION IC, LINEAR REG ADJ, 2A, 14TSSOP-EP SUPPLIER PART MAXIM MAX8526EUD+ Maxim MAX1793EUE-33 FOX FOXSDLF-120-20 ConnorWinfield MX010-025.0M VEC MC853X4-035W RAKON P5299LF TSW-103-07-T-D UB2, UB7, UB17, UB18, UB21 5 XB1 1 IC, LINEAR REGULATOR, 1.5W, 3.3V OR ADJ, 1A, 16 PIN TSSOP-EP XTAL, HC49SD, 12.0000MHz +/-50PPM, CL=20PF Y1 1 OSCILLATOR LVCMOS, 3.3V, 25 MHZ, 4 PIN SMD Y2 1 Y3 1 OSCILLATOR, VECTRON OCXO, 3.3V, 12.8 MHZ, 5 PIN THROUGH-HOLE OSCILLATOR, RAKON TC-OCXO, 3.3V, 10MHZ RFPO-30-RX-C-LF J9 1 TERMINAL STRIP, 6 PIN, DUAL ROW, VERT NOT POPULATED Samtec NOT POPULATED TP14 1 TESTPOINT, 1 PLATED HOLE RED KEYSTONE 5000R U3,UB1,UB8 3 TINYLOGIC HIGH SPEED 2-INPUT AND GATE, 5 PIN SOT23 Fairchild NC7SZ08M5 Not Populated: DS5, DS6, DS7, DS8, DS9, DS10, DS11, DS12, DS13, DS14 J7, J12, J29, J30, J31, J32, J33, JP2, JP20, JP21, JP22, JP31, JP32, JP33, JP34 U5, U7 8. Schematics The MAX24188 EV Kit board design is a bill of materials modification of the MAX24287 EV Kit. See the following pages for the MAX24287 EV Kit schematics. The list of components that are not populated in the MAX24188 EV Kit board is shown at the end of section 7 above. 9. Ordering Information PART MAX24188EVKIT 10. TYPE Evaluation Kit Revision History REVISION DATE 10/11 2012-05 DESCRIPTION Initial Release Reformatted for Microsemi. No content change. 19 8 7 6 5 4 3 2 1 MAX24287 EVKIT Rev_B D D TXD7 TXD6 TXD5 TXD4 30.0 30.0 30.0 30.0 V1_2 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52 R12 R20 R23 R44 REFCLK RST_DUT GTXCLK SCLK SDI SDO GPIO1 GPIO2 GPIO3 TX_ER TX_EN V3_3 TP4 TP7 TP3 U6 TQFN TP10 C REFCLK RST_N GTXCLK DVDD3.3 SCLK SDI SDO GPIO1 GPIO2 GPIO3 TX_ER TX_EN DVDD1.2 TXD7 TXD6 TXD5 TXD4 C 2 100 R15 1 2 TCLKN TCLKP TVDD33 TDN TDP TVDD12 RVDD33 RDP RDN RVDD12 MAX24287, MAX24288 OR MAX24188 TXD3 TXD2 TXD1 TXD0 DVSS TXCLK/RCLK1 CS_N JTDO JTRST MDIO MDC RXCLK DVDD3.3 RXD0 RXD1 RXD2 RXD3 GVDD12 ALOS DVDDD3.3 JTCK JTMS JTDI GPO1 GPO2 CRS/COMMA COL RX_ER RX_DV DVDD1.2 RXD7 RXD6 RXD5 RXD4 100 TP1 TP2 GVSS CVDD3.3 CVDD1.2 CVSS TCLKN TCLKP TVDD3.3 TDN TDP TVSS TVDD1.2 RVDD3.3 RDP RDN RVSS RVDD1.2 NC CS_N JTDO JTRST 30.0 R16 MDC R52 30.0 TXCLK MDIO R51 R53 R54 R55 R56 30.0 V3_3 RXCLK 30.0 30.0 30.0 30.0 RXD0 RXD1 RXD2 RXD3 B 30.0 30.0 30.0 30.0 30.0 30.0 30.0 30.0 30.0 30.0 R48 R49 R50 R42 GPO1 GPO2 CRS COL RX_ER RX_DV RXD7 RXD6 RXD5 RXD4 V3_3 TXD3 TXD2 TXD1 TXD0 V1_2 R17 R22 R43 R45 R46 R47 V1_2 ALOS JTCK JTMS JTDI 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 B 51 50 49 48 47 46 45 44 43 42 41 40 39 38 37 36 35 EP 1 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 TP8 17 EP2 TVDD33 TVDD12 R30 A A Top level Hierarchy block TITLE: DATE: MAX24287 EVKIT Rev_B ENGINEER: 8 7 6 5 4 3 07-11-2011 1/11(TOTAL) 1/8 (BLOCK) PAGE: Steve Scully 2 1 8 7 6 5 4 3 2 1 D D Switch Hierarchy block. Contents on page 9 C C REALTEK_SWITCH_DN RXD0 TP5 RXD0 TXD0 TXD0 RXD1 RXD1 TXD1 TXD1 RXD2 RXD2 TXD2 TXD2 RXD3 RXD3 TXD3 TXD3 RXD4 RXD4 TXD4 TXD4 RXD5 RXD5 TXD5 TXD5 RXD6 RXD6 TXD6 TXD6 RXD7 RXD7 TXD7 RX_DV RX_ER RXCLK TP6 GTXCLK TX_EN RX_ER TXCLK RXCLK TX_ER TXD7 TP11 TX_EN TXCLK B GTXCLK LED4 LED6 LED6 LINKA0 LINKA0 LINKA1 LINKA1 RESET LED2 SWITCH_OSC LED5 LED2 CRS LED5 1 J32 LED4 LED1 MDIO COL LED0 LED1 MDC LED0 1 J33 B TP9 RX_DV A MDC MDIO COL 2 2 CRS SWITCH_OSC RESET A Top level Hierarchy block TITLE: DATE: MAX24287 EVKIT Rev_B ENGINEER: 8 7 6 5 4 3 07-11-2011 2/11(TOTAL) 2/8 (BLOCK) PAGE: Steve Scully 2 1 8 7 6 5 4 3 2 1 V3_3 3 NC7SZ86_U BUFFER JP18 2 D 2 2RB82 GPO1 RB87 UB20 1 1 1 1.00K 1 DS15 2 4 330 1 NC7SZ86_U BUFFER DS4 UB6 GPIO1_LED V3_3 1 1 GREEN 2 RB14 4 330 RB84 3 NC7SZ86_U 330 BUFFER JP19 2 2 2 R24 GPO2 RB86 UB19 1 1 1 1.00K 1 D RB85 GREEN 10.0K DS16 2 4 1 GREEN V3_3 3 10.0K V3_3 RB49 10.0K GPIO1 J18 4 RX_DV V3_3 1 1 2 2 2 JP16 2 2 JP23 2 1 RXD7 V3_3 V3_3 1 3 10.0K 3 RB57 1 2 2 TXCLK 1 JP24 2 2 GPIO2 1 RXD5 49.9 1 2 2 1 JP26 2 2 10.0K 10.0K RB64 2 JP30 2 1 RXD0 V3_3 V3_3 3 3 1 10.0K R13 RB69 RXD1 J24 4 2 2 1 2 2 JP12 10.0K 1 GPIO3 JP8 GPIO3_SMB 30.0 TX_ER JP29 1 3 RB63 J17 2 JP28 2 1 RXD2 V3_3 10.0K 1 A 3 3 1 1 RB28 2 3 1 BUFFER 2 10.0K 2 RB77 49.9 10.0K 2 4 NC7SZ86_U UB9 1 J28 11 RXD3 1 2 2 JP27 10.0K 1 JP3 2 1 A 2 1 2 JP11 1 GPIO3 RB37 3 GPIO3_SMB UB10 1 V3_3 1 BUFFER RB25 JP13 1 RXD4 NC7SZ86_U V3_3 B R26 COL RB78 2 4 V3_3 V3_3 10.0K J27 11 1 2 V3_3 RB35 10.0K 2 JP25 J16 3 JP7 GPIO2_SMB 3 3 2 30.0 UB11 1 2 1 JP10 GPIO2 1 RB27 1 BUFFER 1 1 1 2 2 4 NC7SZ86_U 3 RB23 2 JP4 1 RB79 1 3 B 3 UB12 2 3 J23 BUFFER 1 10.0K NC7SZ86_U JP15 10.0K 1 RXD6 V3_3 GPIO2_SMB Top level Hierarchy block TITLE: DATE: MAX24287 EVKIT Rev_B ENGINEER: 7 6 5 4 3 07-11-2011 3/11(TOTAL) 3/8 (BLOCK) PAGE: Steve Scully 8 C 10.0K RB80 V3_3 JP17 10.0K 2 R25 J26 11 GPIO1_LED RB81 CRS RB71 1 JP6 GPIO1_SMB 30.0 V3_3 3 2 RX_ER 1 3 2 1 3 1 1 1 RB29 1 GPIO1 1.00K 10.0K BUFFER RB36 1 1 UB13 1 2 2 RB26 2 4 NC7SZ86_U 2 1 JP9 RB24 JP5 1 2 49.9 3 GPIO1_SMB 3 UB14 V3_3 C 2 JP14 J22 BUFFER 3 NC7SZ86_U 2 1 8 5 IN4 7 SHDN* 7 2 IN1 OUT1 12 3 IN2 OUT2 13 4 IN3 OUT3 14 OUT4 15 RST* 6 11 GND 10 1.0UF CB10 6 CB39 5 CB40 CB66 1.0UF 15 RST* 6 7 SHDN* V5_0 LB8 3.3V 7 2 IN1 OUT1 12 3 IN2 OUT2 13 4 IN3 OUT3 14 OUT4 15 RST* 6 IN4 V3_3 4 SET 11 GND 10 SHDN* SET 11 GND 10 U2 V1_2 V3_3 1 3.3V R60 330 4 MAX1793 3 MAX6709AUB IN1 5.0V PWRGD1 VCC 2 IN2 3.3V PWRGD2 8 3 IN3 2.5V PWRGD3 7 IN4 ADJ TP12 PWRGD4 GND 12 OUT 13 4 IN FB 9 5 IN GND EP 8 TP14 GND_TP2 GND_TP4 GND_TP3 GND_TP1 V5_0 6 TITLE: MAX24287 EVKIT Rev_B ENGINEER: Steve Scully 2 DB1 15 MAX1793 V5_0 3 4 1 CENTER POST 2 BARREL 9 10 PAGE: 1 10UF C26 U8 0.01UF CB145 0.0 R18 2 1.0UF C22 1.40K R27 OUT IN 11 MAX8526EUD R28 IN 3 OUT 1.00K 2 10 0.0 EN OUT R57 0.01UF C24 1 ADJ 1 14 OUT4 CB26 OUT3 IN4 0.01UF IN3 5 2 4 TP13 1.0K 13 1.0K OUT2 10UF CB4 3.3V V3_3 RB9 5 3 1.0UF CB128 IN2 1.0K 3 1 470UF 12 1.0UF C27 UB21 2 CB6 OUT1 10UF CB146 IN1 10UF C23 2 1.0UF CB142 V5_0 10UF C21 4 1.0UF CB135 10UF C19 1.0UF CB143 5 RB4 RB1 1.0UF CB127 10UF C25 V1_2 CB41 0.01UF C17 1.0UF CB124 LB7 1.0UF 0.01UF CB110 1.0UF CB77 0.01UF C10 RVDD33 V3_3 1.0UF CB37 1.0UF CB55 1.0UF CB38 RVDD12 1.0UF C14 1.0UF C13 10UF C16 0.01UF CB101 1.0UF CB104 10UF C15 0.01UF CB80 1.0UF CB79 TVDD33 6 1.0UF 1.0UF CB113 10UF CB19 1UH 1.0UF CB36 1.0UF 0.01UF CB85 TVDD12 LB6 1.0UF CB134 1.0UF CB84 0.01UF CB96 1.0UF CB95 10UF CB20 0.01UF 1UH 1.0UF UB2 CB114 0.01UF CB88 1UH CB42 V5_0 1.0UF CB123 10UF CB140 10UF C11 1.0UF CB87 LB5 CB133 SET 0.01UF CB78 1.0UF CB115 10UF CB112 1.0UF CB99 0.01UF CB105 1UH 10UF CB5 1.0UF C12 C 0.01UF CB111 CB3 0.01UF 2 CB16 1 470UF 7 1.0UF A 1.0UF CB14 10UF CB139 1.0UF CB141 D 10UF CB9 2 CB144 1 470UF 8 1 V1_2 TP15 D UB18 J1 B ADJ INPUT RANGE IS 0.609V TO 0.635V V3_3 Top level Hierarchy block DATE: 07-11-2011 4/11(TOTAL) 4/8 (BLOCK) C NC MAX1793 V5_0 B MAX6709 GREEN DS1 DS2 DS3 5 A 8 7 6 5 4 3 2 1 J21 J15 1 TPB2 3 TPB3 5 8 RPB4 1 TPB1 7 7 2 TPB6 9 MDIO 6 SFP_I2C_SDA 5 33 3 11 4 13 1 4 5 6 7 8 9 10 11 12 13 14 J11 SCLK 2 2 3 CS_N 2 D 1 V5_0 4 1 RPB2 8 1 2 SDI 3 SDO 4 73 33 65 57 9 6 8 TPB5 8 RPB3 1 10 TPB4 7 2 12 6 14 5 33 1 2 3 4 5 6 7 8 9 10 2 TPB7 4 TPB8 6 TPB9 8 TPB10 J9 1 10 COM_BCLK 3 5 CS_N 1 2 3 4 5 6 2 MDC 4 SFP_I2C_CLK 6 SCLK CONN_10P COM_BCLK 3 D CONN_6P_U SDI 4 SDO CONN_14P EXTERNAL SBC CONNECTOR DS31400DK CONNECTOR C J12 Processor Hierarchy block. Contents on page 8 1 MC9S08JM_BLOCK PROC_GPIO2 LED1 PROC_GPIO3 LED2 PROC_GPIO4 LINKA0 PROC_GPIO5 LED4 PROC_GPIO8 LINKA1 5 PROC_GPIO0 7 PROC_GPIO1 9 PROC_INTREQ 2 4 5 6 7 8 9 10 2 4 SFP_I2C_CLK 6 SFP_I2C_SDA 8 MDC 10 MDIO B PULLUPS ARE IN PROCESSOR BLOCK PROCESSOR TRISTATES PIN AT END OF CYCLE J13 SPI1_MISO 1 SPI1_MOSI 3 SPI1_SCK 5 SPI1_CS 7 9 RESET PROC_GPIO7 LED6 I2C_SDA_P 1 3 CONN_10P PROC_GPIO6 LED5 3 PROC_GPIO9 1 2 3 4 5 6 7 8 9 10 2 SDO 4 SDI 6 8 SCLK J34 V3_3 CS_N 1 10 3 5 CONN_10P 7 9 A 3.08V U1 MAX811_U V3_3 3 MR* VCC 4 3 1 GND RESET* 2 TDI 5 TMS VCC TCK GND RST 0.0 RB8 TITLE: JTDI 6 JTMS 8 JTCK 10 JTRST V3_3 A WHEN NOT IN JTAG MODE INSTALL JUMPERS ON BOTTOM 4 ROWS DATE: MAX24287 EVKIT Rev_B 6 5 4 3 07-11-2011 5/11(TOTAL) 5/8 (BLOCK) PAGE: Steve Scully 7 JTDO 4 Top level Hierarchy block RST_DUT 0.0 ENGINEER: 8 2 RB3 10UF CB1 4 2 10UF CB2 1 TDO CONN_10P RESET SW1 1 3 10K LED0 I2C_SCL_P RB83 B C 2 1 8 7 6 5 4 3 2 1 3.3V LB10 UB17 OUT3 14 IN4 OUT4 15 RST* 6 7 SHDN* SET 11 GND 10 10UF C18 SFP_VCCR 100O100MZH 0.01UF CB93 IN3 10UF CB56 4 D LB11 1.0UF CB92 12 13 SFP_3.3V_REG 1.0UF CB102 OUT2 0.01UF CB103 OUT1 IN2 100O100MZH 10UF C9 IN1 3 1.0UF CB129 10UF C20 1.0UF CB62 2 5 SFP_VCCT TP16 V5_0 D SFP_3.3V_REG MAX1793 1 RPB11 8 2 C J30 10K 3 4 SFP_DEV_DETECT 1 3 SFP_LOS SFP_I2C_SDA 5 SFP_I2C_CLK 7 SFP_TX_FAULT 9 1 2 3 4 5 6 7 8 9 10 2 4 10 SFP_TX_DISABLE 6 SFP_I2C_SDA 5 SFP_I2C_CLK SFP_3.3V_REG ALOS 6 8 SFP_TX_FAULT 7 1 RPB10 8 SFP_RATE 2 SFP_LOS 7 10K 3 SFP_TX_DISABLE 4 SFP_RATE 6 C PULLUPS FOR OPEN DRAIN PINS 5 CONN_10P B B U7 20 VEET TDN 19 TD- TDP 18 TD+ 17 VEET SFP_VCCT 16 VCCT SFP_VCCR 15 VCCR 14 VEER BUFFER SFP_TX_DISABLE MOD-DEF2 4 SFP_I2C_SDA MOD-DEF1 5 SFP_I2C_CLK MOD-DEF0 6 SFP_DEV_DETECT RATE 7 RDP 13 RD+ LOS 8 RDN 12 RD- VEER 9 11 VEER VEER 10 CGND CGND CGND CGND CGND CGND CGND CGND CGND CGND CGND NC7SZ86_U 1 SFP_TX_FAULT 3 TX_DISABLE SFP_HOST 1 2 UB154 2 1 DS9 RED 1 RPB9 8 2 7 3 4 330 SFP_3.3V_REG 6 5 NC7SZ86_U SFP_RATE BUFFER 1 SFP_LOS UB164 1 DS10 2 A RED 21 22 23 24 25 26 27 28 29 31 30 A VEET TX_FAULT Top level Hierarchy block TITLE: DATE: MAX24287 EVKIT Rev_B ENGINEER: 8 7 6 5 4 3 07-11-2011 6/11(TOTAL) 6/8 (BLOCK) PAGE: Steve Scully 2 1 8 7 6 5 4 3 2 1 _POW=V3.3_OSCBUF J10 UB1 1 1 3.3V RB2 V5_0 6 7 SHDN* SET 11 GND 10 V3.3_OSC J4 BUFFER Y3 osc_racon MAX1793 NC 3 5 J19 2 4 6 2 1 4 3 6 5 1 VDD_MOCXO 3 VDD_OCXO 5 VDD_POSC 2 NC NC OSC_MINIOCXO R5 4 GND OUT CONN_6P_U C 30 6 VCC 10MHZ TCXO _POW=V3.3_OSCBUF JMP_3 1 6 7 5 V3.3_OSCBUF GND C R4 3 30 B 5 NC7SZ08 1 2 3 4 5 6 4 REFCLK 6 RST_DUT R6 1 RF_OUT 4 C 2 30 OSC_OCXO B 0.01UF CB27 10UF C4 10UF CB24 1.0UF CB21 OSC_MC853X4 1.0UF CB8 0.01UF CB12 1.0UF C2 0.01UF CB7 1.0UF CB13 1.0UF CB28 1.0UF CB23 1.0UF CB34 1.0UF CB25 10UF CB11 2 J14 CONN_6P_U 1 A 2 SUPPLY_V LB1 U3 JP1 Y2 100O100MZH 1 30 UB4 4 1 J3 1 RB5 NC7SZ86_U 1 B UB3 4 GND=GND RN1 RST* BUFFER 1 1.0K 15 10K 14 OUT4 NC7SZ86_U RB10 OUT3 IN4 D GND=GND RST_DUT 3 IN3 5 1 1 4 NC7SZ08 0.01UF C3 OUT2 30 B J25 TP17 1.0UF C1 IN2 13 10UF CB15 12 IN1 10UF CB29 OUT1 3 1.0UF CB31 10UF CB32 2 1.0UF CB30 D R1 4 C 2 49.9 UB7 A Y1 OSC_TCXO 1 VC VS _POW=V3.3_OSCBUF 4 UB8 1 2 GND RF_OUT 3 2 R10 OSC_LOWCOST R9 30 RST_DUT A GND=GND 3 0.01UF C8 1.0UF CB35 10UF CB33 NC7SZ86_U BUFFER J7 UB5 JP2 R7 SWITCH_OSC 30 49.9 1 1 RB11 REV_A NOTE: UB1, UB8 AND U3 HAVE REWORK TO CONNECT PIN 2 TO DUT_RST THE REWORK IS IN THE FORM OF LIFTED PINS + 20 AWG WIRE COMPONENT RN1 HAS BEEN ADDED TO PIN2 OF J7 THE SCHEMATIC HAS BEEN UPDATED TO MATCH THE PCB 4 C B NC7SZ08 30 A A Top level Hierarchy block TITLE: J8 DATE: MAX24287 EVKIT Rev_B 1 ENGINEER: 8 7 6 5 4 3 07-11-2011 7/11(TOTAL) 8/8 (BLOCK) PAGE: Steve Scully 2 1 5 4 1 3 5 1 2 3 4 5 2 PTA1 C PTA4 33 PTA5 34 PTB0/MISO2/ADP0 PTD6 52 35 PTB1/MOSI2/ADP1 PTD7 53 USB MC9S08JM U4 IO PROC_GPIO6 36 PTB2/SPSCK2/ADP2 PTE0/TXD1 13 IO PROC_GPIO7 37 PTB3/SS2/ADP3 PTE1/RXD1 14 IO PROC_GPIO8 38 PTB4/KBIP4/ADP4 PTE2/TMP1CH0 15 IO PROC_GPIO9 39 PTB5/KBIP5/ADP5 PTE3/TPM1CH1 16 40 PTB6/ADP6 PTE4/MISO1 17 41 PTB7/ADP7 PTE5/MOSI1 18 I2C_SCL_P I2C_SDA_P VBUSDET 10.0K 60 PTC0/SCL PTE6/SPSCK1 19 61 PTC1/SDA PTE7/SS1 20 62 PTC2 PTF0/TPM1CH2 4 63 PTC3/TXD2 PTF1/TPM1CH3 5 PTC4 PTF2/TPM1CH4 6 PTC5/RXD2 PTF3/TPM1CH5 7 9 PTC6 PTF4/TPM2CH0 RESET 8 3 RESET* PROC_INTREQ 2 56 BKGDMS USBDP USBDN 2 RB19 PTF5/TPM2CH1 11 IRQ/TPMCLK PTF6 12 BKGD/MS PTF7 10 R2 24 USBDP PTG0/KBIP0 26 33.2 23 USBDN PTG1/KBIP1 27 PTG2/KBIP6 54 PTG3/KBIP7 55 PTG4/XTAL 57 PTG5/EXTAL 58 R3 SPI1_CS IO SPI1_MISO IO SPI1_MOSI IO SPI1_SCK IO 2 4 5 5 6 6 7 7 8 8 9 10 SPI1_MISO SPI1_MOSI SPI1_SCK SPI1_CS B 12.0000MHZ XB1 1 2 A R8 PROC_GPIO0 IO PROC_GPIO1 IO Processor Hierarchy block. MOUNTING HARDWARE H1 H2 H3 H4 H5 H6 H7 4 4 4 4 4 4 4 1 7 6 5 1 1 4 1 1 1 TITLE: Instantiated on page 5 07-11-2011 8/11(TOTAL) 1/1 (BLOCK) ENGINEER: PAGE: Steve Scully 3 1.00M DATE: MAX24287 EVKIT 1 22PF IO 10 C C7 PROC_INTREQ 4 CONN_10P 59 IO 46 I2C_SDA_P 47 IO 22 I2C_SCL_P VSS VSSAD VREFL VSSOSC 5 2 1 2 RB20 RB18 1 2 RB15 1 2 RB16 1 2 RB17 9 51 32 PROC_GPIO5 2 1 3 1 RB13 1 RB21 50 PTD5 PROC_GPIO4 IO IO 1K PULLUPS 8 PTD4/ADP11 IO 1 1 RB22 2 2 2 1 A 49 PTA3 B 1 2 3 4 48 PTD3/KBIP3/ADP10 PTA2 64 VDD DATDAT+ GND PTD2/KBIP2/ACMPO 30 31 1 V3_3 3 PROC_GPIO3 RB7 VBUS 1 43 PROC_GPIO2 VBUS J2 42 PTD1/ADP9/ACMP- IO 10K 6 PTD0/ADP8/ACMP+ IO RB6 4 6 PTA0 29 V3_3 22PF BKGDMS 28 PROC_GPIO1 VDD VDDAD VREFH VUSB33 21 V5_0 PROC_GPIO0 D JB1 C6 6 J6 4.7UF 6 CB17 5 2 4 D J5 1 25 4 45 5 2 44 VBUS 1 3 .1UF 3 4.7UF 1 CONN_6P_U 2 CONN_6P_U V5_0 CB18 JUMPER 1+3, 4+6 TO POWER FROM USB ONLY 3 .1UF 6 CB22 7 C5 8 2 1 1 1.0K 2 3 4 2.49K 5 6 AVDD33 7 AVDD12 8 P0MDIAP 9 P0MDIAN 10 11 P0MDIBP 12 P0MDIBN 13 AVDD12 14 AVDD33 15 P0MDICP 16 P0MDICN 17 18 19 P0MDIDP 20 P0MDIDN 21 AVDD12 22 AVDD12 23 AVDD33 24 P1MDIAP 25 P1MDIAN 26 27 28 P1MDIBP 29 P1MDIBN 30 AVDD12 31 AVDD33 32 P1MDICP 33 P1MDICN 34 35 P1MDIDP 36 P1MDIDN 37 AVDD12 38 AVDD33 RB60 RB65 B 8 VDD12 DVDD VDD12 VDDIO RESET AVDDPLL AVDD33 AVDD33 103 104 105 RXD0 106 RXD1 107 RXD2 108 RXD3 109 110 RXD4 111 RXD5 112 RXD6 113 RXD7 114 115 MDIO 116 MDC LED3 117 LED7 118 119 0.0 R21 120 121 FLOAT122 122 123 SWITCH_OSC 124 125 126 127 128 RX_DV 129 7 A 8363S P2MRXDV/P2PTXEN/P2MRXCTL/P2MSRSDV VDD12 P2MRXD0/P2PTXD0 P2MRXD1/P2PTXD1 P2MRXD2/P2PTXD2 P2MRXD3/P2PTXD3 DVDD P2MRXD4 P2MRXD5 P2MRXD6 P2MRXD7 VDD12 SDA/MDIO SCL/MDC LEDDA/LED3/LEDMODE[0] LEDCK/LED7/LEDMODE[1] VDDIO RESET# AVDDPLL RSVD AVSSPLL XTAL1 XTAL2 AVDD33 AGND AVDD33 6 RTL8363S 5 4 BGPIO1 VDD12 BGPIO2 DVDD LEDSPSEL ENJF VDD12 INT BGPIO3 WAKEUP RSVD RSVD AVDD12 RSVD RSVD AGND AVDD12 AGND RSVD RSVD AVDD12 RSVD AGND RSVD RSVD RSVD 4 FLOAT39 64 63 VDD12 62 61 DVDD 60 LESSPSEL 59 EN_JUMBO 58 VDD12 57 56 55 54 RB41 53 RB39 1.00K 52 AVDD12 1.00K 51 FLOAT51 50 FLOAT50 49 48 AVDD12 47 46 FLOAT46 45 FLOAT45 44 AVDD12 43 42 RB40 1.00K 41 RB43 40 1.00K 39 RB42 1.00K 3 1.00K 5 R63 GTXCLK TX_EN VDD12 TXD0 TXD1 TXD2 TXD3 DVDD TXD4 TXD5 TXD6 TXD7 VDD12 RXCLK TXCLK CRS 6 1.00K 102 101 R31 30.0 100 R40 30.0 99 DVDD 98 COL 97 96 R29 30.0 95 R41 30.0 94 93 R32 30.0 92 R33 30.0 91 R34 30.0 90 R35 30.0 89 88 R39 30.0 87 R36 30.0 86 R37 30.0 85 R38 30.0 84 RX_ER 83 82 TXDLY 81 RXDLY 80 DVDD 79 P2IF0 78 P2IF1 77 P2IF2 76 P2LINKSTA 75 VDD12 74 P2SPD0 73 P2SPD1 72 LED0 71 LED1 70 DVDD 69 LED2 68 LED4 67 LED5 66 LED6 65 7 R62 P2MRXC/P2TXC/P2MRCLK P2MTXC/P2PRXC P2MCRS/P2PCRS DVDD P2MCOL/P2PCOL P2MGTXC P2MTXEN/P2PRXDV/P2MTXCTL VDD12 P2MTXD0/P2PRXD0 P2MTXD1/P2PRXD1/DISPBLK P2MTXD2/P2PRXD2/RSVD P2MTXD3/P2PRXD3 DVDD P2MTXD4/FWMODE[0] P2MTXD5/FWMODE[1] P2MTXD6/PHYADR[3] P2MTXD7/PHYADR[4] VDD12 P2MRXER/P2PTXER ENEEPROM TXDLY RXDLY DVDD P2IF[0] P2IF[1] P2IF[2] P2LNKSTA VDD12 P2SPD[0] P2SPD[1] LED0/AGPIO0 LED1/AGPIO1 DVDD LED2/AGPIO2 LED4/AGPIO3 LED5/AGPIO4 LED6 BGPIO0 C NC NC ATEST MDI_REF AGND AVDD33 AVDD12 P0MDIAP P0MDIAN AGND P0MDIBP P0MDIBN AVDD12 AVDD33 P0MDICP P0MDICN AGND AGND P0MDIDP P0MDIDN AVDD12 AVDD12 AVDD33 P1MDIAP P1MDIAN AGND AGND P1MDIBP P1MDIBN AVDD12 AVDD33 P1MDICP P1MDICN AGND P1MDIDP P1MDIDN AVDD12 AVDD33 8 3 2 D U5 TITLE: MAX24287 EVKIT ENGINEER: Steve Scully 2 1 TXD0 TXD1 TXD2 TXD3 TXD4 TXD5 TXD6 TXD7 (MII) TX_ER TX_EN TXCLK CRS COL IO FUNCTION FOR GMII MODE RX_ER RX_DV RXD7 RXD6 RXD5 RXD4 RXD3 RXD2 RXD1 RXD0 RXCLK RESET GTXCLK SWITCH_OSC MDIO MDC Switch Hierarchy block. OUT OUT OUT OUT OUT OUT D OUT OUT OUT IN IN IN IN IN IN IN IN IN IN IN IN C IN IN IN V3_3 IN IN IN IO IN B EPAD A Instantiated on page 2 DATE: PAGE: 07-11-2011 9/11(TOTAL) 1/3 (BLOCK) 1 8 7 6 5 4 3 2 J31 1 J29 D D P0MDIAP 2 CMR CHOKES TD0+ 0.01 UF X4 P0MDIAN 3 750 X4 2 P1MDIAP CMR CHOKES TD0+ J1 MX0+ 0.01 UF X4 TD0- P1MDIAN 3 P1MDIBP 4 P1MDIBN 5 750 X4 J1 MX0+ TD0- J2 MX0- P0MDIBP 4 P0MDIBN 5 J2 MX0- TD1+ TD1+ J3 MX1+ J3 MX1+ TD1- TD1- J6 MX1- P0MDICP 6 J6 MX1- TD2+ 6 P1MDICP TD2+ J4 MX2+ C P0MDICN 7 J4 MX2+ TD2- 7 P1MDICN J5 MX2- P0MDIDP 8 J5 MX2- TD3+ P1MDIDP 8 P1MDIDN 9 TD3+ J7 MX3+ P0MDIDN 9 J7 MX3+ TD3J8 MX31000PF, 2KV 1 13 GREEN P11 P12 GND 8 RPB5 1 7 2 14 6 330 B TD3J8 MX3- LINKA0 IN 1 P11 P12 GND 3 8 RPB6 1 7 2 14 6 330 LINKA1 IN 3 10 15 CHGND SH1 YELLOW P13 P14 SH2 5 4 LED3 11 12 16 conn_hfj11_1g41e_l12rl 15 CHGND SH1 P13 P14 LED0=GIG_LINK/ACT LED1-100_LINK/ACT LED2=10_LINK/ACT LED3=DUP/COL 8 RPB8 1 LED0 8 RPB7 1 SH2 7 2 LED1 7 6 3 LED2 6 5 4 LED3 DS5 2 330 5 3 DS6 LED7 B DS7 SWITCH1 LED4=GIG_LINK/ACT LED5-100_LINK/ACT LED6=10_LINK/ACT LED7=DUP/COL LED4 8 RPB13 1 7 2 LED5 7 6 3 LED6 6 5 4 LED7 DS11 2 330 5 3 OUT LED2 OUT LED4 OUT LED5 OUT LED6 OUT DS13 DS14 Switch Hierarchy block. TITLE: DATE: MAX24287 EVKIT 07-11-2011 ENGINEER: PAGE: 10/11(TOTAL) Steve Scully 6 5 4 A DS12 4 4.7K OUT LED1 V3_3 DS8 8 RPB12 1 LED0 GREEN 4 4.7K 7 4 16 conn_hfj11_1g41e_l12rl SWITCH0 A 5 YELLOW INDICATIONS FOR PARALLEL MODE0 8 13 GREEN 1000PF, 2KV 10 11 12 C TD2- 3 2/3 (BLOCK) 2 1 8 7 6 5 4 3 2 1 V3_3 P2SPD[1:0] STRAP OPTIONS 00: 10M 01: 100M 10: 1000M EN_JUMBO=0: NO JUMBO FRAME EN_JUMBO=1: JUMBO FRAME EN_JUMBO IS DRIVEN BY P2SPD[1] 3 2 JP32 RB31 CB75 3 P2SPD1 JP22 EN_JUMBO 2 NO DELAY 2 10.0K 2 10.0K 2 10.0K 2 10.0K 3 CB117 0.01UF 1.0UF CB107 1 ADD 1.5NS DELAY TO P2MGRXC 2 RXDLY 1 LB4 RB56 1 CB47 CB61 V3_3 2 2 RB53 0.01UF 1 0.01UF 1 CB82 2 CB72 0.01UF 1 CB60 0.01UF 0.01UF 2 1.0UF CB52 1 2 2 1 1.0UF CB45 1.0UF CB58 1 2 1 1.0UF CB94 1 2 1.0UF CB53 2 1 1.0UF CB86 1 2 2 1.0UF CB73 1 2 1.0UF CB67 1.0UF CB57 1 2 1.0UF CB89 2 1 1 2 10UF CB46 2 2 CB48 3.3UF 1 1 AVDD12 1 RB45 2 P2LINKSTA PORT2 LINK 10.0K 2 LED3 LEDMODE[0] 10.0K 2 LED7 LEDMODE[1] 10.0K 1 RB73 LB14 1 RB72 0.01UF CB108 1 UP 2 CB90 0.01UF 2 2 CB59 0.01UF 1 1 0.01UF CB109 1 2 CB68 0.01UF 1 2 1.0UF CB50 1.0UF CB51 2 1 1.0UF CB122 2 1 1.0UF CB69 2 1 1.0UF CB74 2 1 1.0UF CB91 2 1 1.0UF CB121 2 1 10UF CB132 1 2 2 2 CB138 3.3UF 1 1 VDD12 100O100MZH Switch Hierarchy block. TITLE: DATE: MAX24287 EVKIT 07-11-2011 ENGINEER: PAGE: 11/11(TOTAL) Steve Scully 8 7 B 2 LESSPSEL LED MODE PARALLEL 10.0K 2 TXD2 10.0K 2 TXD0 10.0K 2 TXD1 LED BLINK ON 10.0K RB54 A TXD7 V3_3 RB38 100O100MZH C TXD6 JP31 NO DELAY 2 2 1 10UF CB130 2 1 V3_3 3.3UF 1 CB136 2 B RB44 ADR[0] ADR[1] RB50 TXD5 FWMODE[1] TXD4 RB52 FWMODE[0] SWITCH ADDRESS: 0=16, 1=17, 2=18 FWDMODE=STORE-FORWARD RB51 1 LB12 AVDDPLL JP20 1 V3_3 R14 100O100MZH 1.0K JP34 2 2 TXDLY 2 2 10.0K ADD 1.5NS DELAY TO P2MGTXC 3 0.01UF CB118 1 1.0UF CB106 1 2 1 3.3UF 10UF CB131 1 2 V3_3 RB33 1 2 1 LB13 V1_2 JP21 V3_3 3 RB30 1.0K VDDIO 2 1.0K 1 0.01UF 2 2 P2IF2 100O100MZH RB34 V3_3 C CB137 P2SPD0 JP33 1 CB83 0.01UF 1 1 CB63 0.01UF 1.0UF CB76 1 2 2 1.0UF CB71 1 2 1.0UF CB100 1.0UF CB119 1 2 1 2 2 2 3.3UF 1 100O100MZH 1.0UF CB49 2 1 10UF CB44 1 DVDD CB43 2 1.0K 1 P2IF1 LB3 D V3_3 V3_3 3 2 2 1 CB65 0.01UF 0.01UF CB120 P2IF[2:0] STRAP OPTIONS 000: GMII/PHY MODE MII 001: GMII/MAC MODE MII 010: RGMII 011: RMII 3 1 1 1 1.0UF CB54 1 2 CB97 1.0UF CB116 1 2 0.01UF 1.0UF CB64 1 2 2 1.0UF CB81 1 2 RB32 1.0K 1.0UF CB98 1.0UF CB70 1 2 2 1 3.3UF CB126 2 10UF CB125 2 1 P2IF0 AVDD33 100O100MZH 1 D LB9 V3_3 6 5 4 3 3/3 (BLOCK) 2 1 A Microsemi Corporation (NASDAQ: MSCC) offers a comprehensive portfolio of semiconductor solutions for: aerospace, defense and security; enterprise and communications; and industrial and alternative energy markets. Products include high-performance, high-reliability analog and RF devices, mixed signal and RF integrated circuits, customizable SoCs, FPGAs, and complete subsystems. Microsemi is headquartered in Aliso Viejo, Calif. Learn more at www.microsemi.com. Microsemi Corporate Headquarters One Enterprise, Aliso Viejo CA 92656 USA Within the USA: +1 (949) 380-6100 Sales: +1 (949) 380-6136 Fax: +1 (949) 215-4996 © 2012 Microsemi Corporation. All rights reserved. Microsemi and the Microsemi logo are trademarks of Microsemi Corporation. All other trademarks and service marks are the property of their respective owners.