Fujitsu Semiconductor Europe GmbH User Guide FSEUMCU-UG-9E0005-10 FCR4 FAMILY FCR4 CLUSTER SERIES STARTERKIT SK-MB9DF125-001 / -002 / -003 USER GUIDE SK-MB9DF125-001 / -002 / -003 Revision History Revision History Date 2011-09-29 Issue V1.0, MKoehl First release Applies To Order-No. Reference Description SK-MB9DF125-001 TRACE Full-featured variant with independent trace-capability. SK-MB9DF125-002 SOCKET 176-pin socket variant. Tracing blocks some MCUports. SK-MB9DF125-003 SOCKET 240-pin socket variant of SK-MB9DF125-001. If not mentioned otherwise, this guide applies to all boards listed in the table above. Variantspecific features/differences are tagged by the name listed under “Reference”. This document contains 37 pages. UG-9E0005-10 -2- © Fujitsu Semiconductor Europe GmbH SK-MB9DF125-001 / -002 / -003 Abbreviations Abbreviations ARM® ARM® is a registered trademark of ARM Limited in the EU and other countries CAN Controller Area Network FSEU Fujitsu Semiconductor Europe GmbH MCU Microcontroller Unit UART Universal Asynchronous Receiver Transmitter USB Universal Serial Bus © Fujitsu Semiconductor Europe GmbH -3- UG-9E0005-10 SK-MB9DF125-001 / -002 / -003 Warranty and Disclaimer Warranty and Disclaimer The use of the deliverables (e.g. software, application examples, target boards, evaluation boards, starter kits, schematics, engineering samples of IC’s etc.) is subject to the conditions of Fujitsu Semiconductor Europe GmbH (“FSEU”) as set out in (i) the terms of the License Agreement and/or the Sale and Purchase Agreement under which agreements the Product has been delivered, (ii) the technical descriptions and (iii) all accompanying written materials. Please note that the deliverables are intended for and must only be used for reference in an evaluation laboratory environment. The software deliverables are provided on an as-is basis without charge and are subject to alterations. It is the user’s obligation to fully test the software in its environment and to ensure proper functionality, qualification and compliance with component specifications. Regarding hardware deliverables, FSEU warrants that they will be free from defects in material and workmanship under use and service as specified in the accompanying written materials for a duration of 1 year from the date of receipt by the customer. Should a hardware deliverable turn out to be defect, FSEU’s entire liability and the customer’s exclusive remedy shall be, at FSEU´s sole discretion, either return of the purchase price and the license fee, or replacement of the hardware deliverable or parts thereof, if the deliverable is returned to FSEU in original packing and without further defects resulting from the customer’s use or the transport. However, this warranty is excluded if the defect has resulted from an accident not attributable to FSEU, or abuse or misapplication attributable to the customer or any other third party not relating to FSEU or to unauthorised decompiling and/or reverse engineering and/or disassembling. FSEU does not warrant that the deliverables do not infringe any third party intellectual property right (IPR). In the event that the deliverables infringe a third party IPR it is the sole responsibility of the customer to obtain necessary licenses to continue the usage of the deliverable. In the event the software deliverables include the use of open source components, the provisions of the governing open source license agreement shall apply with respect to such software deliverables. To the maximum extent permitted by applicable law FSEU disclaims all other warranties, whether express or implied, in particular, but not limited to, warranties of merchantability and fitness for a particular purpose for which the deliverables are not designated. To the maximum extent permitted by applicable law, FSEU’s liability is restricted to intention and gross negligence. FSEU is not liable for consequential damages. Should one of the above stipulations be or become invalid and/or unenforceable, the remaining stipulations shall stay in full effect. The contents of this document are subject to change without a prior notice, thus contact FSEU about the latest one. This board and its deliverables must only be used for test applications in an evaluation laboratory environment. UG-9E0005-10 -4- © Fujitsu Semiconductor Europe GmbH SK-MB9DF125-001 / -002 / -003 Contents Contents REVISION HISTORY ............................................................................................................ 2 APPLIES TO......................................................................................................................... 2 ABBREVIATIONS ................................................................................................................ 3 WARRANTY AND DISCLAIMER ......................................................................................... 4 CONTENTS .......................................................................................................................... 5 1 OVERVIEW ...................................................................................................................... 7 1.1 Introduction ............................................................................................................. 7 1.2 Features .................................................................................................................. 7 1.3 Kit contents ............................................................................................................. 7 2 HARDWARE .................................................................................................................... 8 2.1 2.2 PCB Overview ......................................................................................................... 8 2.1.1 Top-View ................................................................................................... 8 2.1.2 Bottom View .............................................................................................. 9 Power Supply ........................................................................................................ 10 2.2.1 Input-stage............................................................................................... 10 2.2.2 I/O Supplies ............................................................................................. 10 2.2.3 MCU Core supply .................................................................................... 10 2.2.4 Supply-Rail Monitors (LEDs) .................................................................... 10 2.2.5 Power distribution .................................................................................... 10 2.3 Reset ..................................................................................................................... 11 2.4 MCU Clocks .......................................................................................................... 11 2.5 2.6 2.7 2.4.1 Main Clock ............................................................................................... 11 2.4.2 Sub-Clock (RTC-Clock) ........................................................................... 11 On-Board Peripherals ............................................................................................ 11 2.5.1 UART/USB-Serial Interface...................................................................... 11 2.5.2 CAN-Bus Interface ................................................................................... 12 Expansion Connectors .......................................................................................... 12 2.6.1 Board-to-Board (B2B) Connectors ........................................................... 12 2.6.2 Riser-Board Connector ............................................................................ 12 Debugging Facilities .............................................................................................. 12 3 INSTALLATION ............................................................................................................. 13 3.1 First Contact .......................................................................................................... 13 3.2 Engage .................................................................................................................. 13 3.3 Lifesigns ................................................................................................................ 13 © Fujitsu Semiconductor Europe GmbH -5- UG-9E0005-10 SK-MB9DF125-001 / -002 / -003 Contents 4 CONFIGURATION AND TEST-POINTS ........................................................................ 14 4.1 Jumpers ................................................................................................................ 14 4.2 Headers................................................................................................................. 16 4.3 Test Points ............................................................................................................ 16 5 STATUS DISPLAY ......................................................................................................... 17 6 CONNECTORS .............................................................................................................. 18 6.1 B2B Connectors (J5, J6) ....................................................................................... 19 6.1.1 Connector J5 Pinout ................................................................................ 19 Special Signals ........................................................................................ 19 MCU-Ports ............................................................................................... 19 6.1.2 Connector J6 Pinout ................................................................................ 21 Special Signals ........................................................................................ 21 MCU-Ports ............................................................................................... 22 6.2 Debug Connector (X2)........................................................................................... 24 6.3 Trace Connector (X3) ............................................................................................ 25 6.4 Riser-Board Connector (X6) .................................................................................. 26 6.5 DC In Plug (X4) ..................................................................................................... 28 6.6 CAN-Bus Connector (X5) ...................................................................................... 29 6.7 USB Connector (X7) .............................................................................................. 29 7 KNOWN ISSUES ........................................................................................................... 30 8 TROUBLE SHOOTING .................................................................................................. 31 9 RELATED PRODUCTS.................................................................................................. 32 10 APPENDIX ..................................................................................................................... 33 10.1 Tables 33 10.2 Figures 33 11 INFORMATION IN THE WWW....................................................................................... 34 12 EU-KONFORMITÄTSERKLÄRUNG / EU DECLARATION OF CONFORMITY ............. 35 13 CHINA-ROHS REGULATION ........................................................................................ 36 14 RECYCLING .................................................................................................................. 37 UG-9E0005-10 -6- © Fujitsu Semiconductor Europe GmbH SK-MB9DF125-001 / -002 / -003 Overview 1 Overview 1.1 Introduction The SK-MB9DF125-001 is a quick evaluation board for the Fujitsu FCR4 Cluster series flash microcontroller MB9DF125 (Atlas-L). It can be used stand-alone for software development and testing or as a simple target board to work with the debug system. Optionally, the adapter board ADA-FCR4-MULTIIO-001 is available as plug-under. It extends the capabilities by additional interfaces and headers which provide easy access to the MCU-signals. As an addition to the Multi-IO board, the ADA-FCR4-CLUSTER-001 is available. It provides a complete automotive dashboard solution without separate microcontroller (all signals are controlled from the SK-MB9DF125). It is connected to the Multi-IO board using a flat-cable. 1.2 Features Supports Fujitsu’s FCR4 Cluster series MB9DF125 (Atlas-L) microcontrollers 12V external DC power supply, On-board 5V, 3V3 and 1V2 regulators for I/O- and MCU supply Power-LEDs for all regulated supply-rails Selectable 5V and 3V3 voltage for specific digital (VDP5 and DVCC) and analogue (AVCC5 and AVRH5) power domains Reset-button with LED-indicator On-board voltage supply supervisor In-Circuit serial Flash programming using the JTAG port 4 main crystal oscillator for MCU clock, 32 kHz crystal for sub clock operation (realtime clock) Riser-card connector for external bus-interface (EBI) and high-speed QSPI. Signals not used on Riser-card are routed to b2b connectors. Riser-cards with various memory-types (QSPI NOR-Flash, NAND-Flash, SDRAM) available, passive (all signals passed back to SK-board) card included. All GPIO-pins not used on-board are available thru Board-to-Board connectors. USB to serial converter (FT232R) connected to USART0 provides direct PC-serial connection using a standard USB-A (PC) to Mini-B (SK) cable. One CAN-Bus interface on male D-Sub-09 connector with industry-standard pinout ARM standard 20 pin IDC JTAG connector for flash-programming and debugging Trace-probe connector for 8 (variant -002) or 16 (variant -001 and -003) bit wide tracing Test-points for internal signals 1.3 Kit contents Variant TRACE or variant SOCKET PCB. USB-A to Mini-B cable. Screws with spacers to mount onto a carrier-board or place on the table. MEM-FCR4-001 pass-through Riser-Board. © Fujitsu Semiconductor Europe GmbH -7- UG-9E0005-10 SK-MB9DF125-001 / -002 / -003 Hardware 2 Hardware 2.1 PCB Overview 2.1.1 Top-View A B C D E F G H I J K L M N O P Q R 1 1 2 2 3 3 4 4 5 5 6 6 7 7 8 8 9 9 10 10 11 11 12 12 13 13 14 14 15 15 16 16 17 17 A B C D E F G H I J K L M N O P Q R Figure 2-1: Top View PCB-Rev.1.0 Variant 001: TRACE - U1: MCU – MB9DF125 (Atlas-L) microcontroller in QFP296 package Variant 002: SOCKET - U2: MCU – MB9DF125 (Atlas-L) microcontroller in QFP176 socket Variant 003: SOCKET - U2: MCU – MB9DF125 (Atlas-L) microcontroller in QFP240 socket Q1: 32768Hz RTC-crystal (SubClk), Q2: 4MHz crystal (MainClk) 12V external DC power supply, 5V, 3V3 and 1V2 voltage regulators, S1 power switch Power-LEDs for the 5V0, 3V3 and 1V2 power rails, SW1 Reset-button, Reset-LED X2, X3: debug and trace port connectors, USB (USART-emulation) and CAN connectors UG-9E0005-10 -8- © Fujitsu Semiconductor Europe GmbH SK-MB9DF120-001 / -002 / -003 Hardware 2.1.2 Bottom View A B C D E F G H I J K L M N O P Q R 1 1 2 2 3 3 4 4 5 5 6 6 7 7 8 8 9 9 10 10 11 11 12 12 13 13 14 14 15 15 16 16 A B C D E F G H I J K L M N O P Q R Figure 2-2: Bottom View PCB-Rev.1.0 J5, J6 - Board-to-Board connectors to Multi-IO © Fujitsu Semiconductor Europe GmbH -9- UG-9E0005-10 SK-MB9DF120-001 / -002 / -003 Hardware 2.2 Power Supply The power supply circuit consists of the input-stage and three voltage-regulators. The regulators are switch-mode types (step-down). Having the enables of the lower voltage supplies tied to the next higher voltage supply guarantees correct sequencing in the order required (5V0 → 3V3 → 1V2). Powerdown/disconnect of power-domains and/or -rails is not supported. All regulators are supplied from the input-rail Vin_prot (filtered input voltage, no regulatorstaggering). Headers are connected to each voltage-rail to allow measuring the voltages. They should not be used to power custom electronics. Each stage provides a header connected to connect to the corresponding domain. Care must be taken when connecting to the 1V2-domain as noise on this rail will have much more impact on this rail due to the low absolute voltage. 2.2.1 Input-stage The power-supply connector is a standard DC-plug for a wall-cube adapter. Allowed input voltage ranges from 9 to 12V, the adaptor should have a minimum power-rating of 6W (500mA @ 12V). After the power-switch, a reverse-voltage protection diode (D2) and a TVS (D3) follow. The latter suppresses/damps high voltage surges from the wall-cube which would otherwise pass the following inductor and capacitors. The inductor (L11) filters noise generated on-board, before it reaches the supply-cable which presents a good antenna for EMI. Filtering incoming noise is a bonus. 2.2.2 I/O Supplies The 5V0 and 3V3 supplies use the same regulator-type, each fixed to the desired output-voltage. As with all switching regulators, the designs are critical in terms of switching noise radiation (over the air and along the traces). Each regulator provides up to 3A on its rail. 2.2.3 MCU Core supply The 1V2 supply for the MCU core is generated by a DC/DC switching module providing up to 3A. 2.2.4 Supply-Rail Monitors (LEDs) Each supply-rail has its own LED-indicator. For the 1V2 rail, the LED is driven from the 3V3 rail and just switched from the 1V2 rail. All three rails are additionally monitored by a system-voltage supervisor which generates reset if any rail fails. 2.2.5 Power distribution The three stabilized voltages drive the various MCU power-domains either directly (single-voltage domains MCU_VDD, MCU_VDP3) or through a 3-pin jumper (dual-voltage domains VDP5, DVCC). Additionally, there is a jumper before each domain's EMI-filter to allow injection of external power or measuring current-consumption of the domain. UG-9E0005-10 - 10 - © Fujitsu Semiconductor Europe GmbH SK-MB9DF120-001 / -002 / -003 Hardware 2.3 Reset Board-Reset can be generated by basically two sources. Both are connected to the system-reset which includes the MCU RST_X signal. Both sources can be disconnected from the reset-net by separate jumpers, thus excluding them from generating the reset-signal, U8 generates the reset to the MCU and all other devices if one of the three system-voltages fails (System Voltage Supervisor). It also monitors a push-button, generating a short reset-pulse (~100µs) if this reset-button is pressed shortly. A longer pulse will be generated if the button is pressed for some seconds. Caution: the SVS monitors the on-board generated voltages, not the MCU power-domains. If any of the domains is supplied externally, it is left to the user to provide a proper reset signal (if required). Another reset source comes from the two debugging connectors JTAG and TRACE. Their shared signal can also be disconnected from the internal net. Having the reset-pin on the MCU belonging to the VDP5 domain and the memory-interface pins driven by the VDP3 domain, two reset-signals are required. While RST_X_3V3 is driven together with RST_X_VDP5, it cannot generate a reset by itself. Therefore, all resets must originate from RST_X_VDP5. Both signals are open-drain with a 10kR pull-up to the corresponding MCU power-domain. RST_X_3V3 is only available on the riser-board connector. The b2b-connectors on the rear-side only provide RST_X_VDP5. RST_X_VDP5 also drives a LED which lights when the signal is active (low). On power-up or a press of the reset-button, the LED will flash according to the pulse generated by the SVS. If the reset-button is pressed only for a short time, although the LED also flashes, this cannot be observed directly as this pulse is too short to be detected by the human eye. 2.4 MCU Clocks 2.4.1 Main Clock The MCU is clocked using its internal 4 MHz oscillator as this is the MainClk net, it controls all timing of the MCU. 2.4.2 Sub-Clock (RTC-Clock) Q1 is a 32.768kHz crystal connected to the MCU's real-time clock oscillator. This clock is used to track time, while the other crystal oscillator is disabled. 2.5 On-Board Peripherals The board provides three interfaces for external communication. 2.5.1 UART/USB-Serial Interface Two port-signals (P0_45, P0_47) are connected to a USB-Serial converter chip (FT232R). The ports can be controlled by USART0, thus allowing a serial interface between the MCU and a PC. For the interface-converter, drivers exist for all major operating systems (OSX, Linux, Windows) either built-in (Linux) or for download (Windows). They provide a standard serial interface (“COMport”/”ttyUSB”) to the applications, so any terminal program can be used to transmit data between the MCU and a PC. The interface does not provide hardware-handshake, thus it is left to the software to provide some kind of flow-control and/or resynchronization, if necessary. There is one LED per direction (RX, TX) signalling data-transmission. The two ports can be disconnected from the converter by two jumpers, freeing them for other usage (the two signals are also available on the B2B connector J5). © Fujitsu Semiconductor Europe GmbH - 11 - UG-9E0005-10 SK-MB9DF120-001 / -002 / -003 Hardware The converter chip is powered from the USB-connector, making its operation independent on the power-status of the board. However, as the supply of the serial interface I/O lines is powered from VDP5, the voltages here always match the requirements of the connected port-signals. 2.5.2 CAN-Bus Interface Two ports from the MCU (P2_40, P2_41) are connected to a CAN-Bus transceiver. The CAN-bus itself is connected to a standard D-sub connector. The two signals are also RX and TX of the internal CAN0-controller. As with the UART, jumpers are available for each port to disconnect them from the interface, freeing them for use from the B2B connector J5. 2.6 Expansion Connectors 2.6.1 Board-to-Board (B2B) Connectors On the bottom-side, there are two board-to-board (b2b) connectors (J5, J6). All MCU ports are available here, along with power-supply and additional control-signals like reset. Layout and placement of the SK-MB9DF125-xxx allows to plug a Fujitsu Multi-I/O board (ADAFCR4-MULTIIO-001) under the board, providing direct access to the ports via standard-raster headers along with other features. Alternatively, a custom PCB can be connected. 2.6.2 Riser-Board Connector X6 is a double-sided card-edge connector with 2*70 contacts. All ports providing either HSSPI (high-speed QSPI) or external bus interface (EBI) signals are routed to one side of this connector together with VDP3 and RST_X_VDP3 (VDP3-based reset-signal). The pins opposite of the each port-signal are routed to the B2B connectors. This structure allows to insert various PCBs (“Riser-Cards”) requiring the external bus or highspeed SPI without passing the long path through the expansion connectors and a plug-under board. With the optimized routing of all signals, the full speed of the two interfaces can be utilized, allowing connection to fast QSPI Flash-devices, SDRAMs or other critical hardware. Ports not used for a particular application must be passed-through by the riser-card. For example, the default card shipped with the starter kit consists completely of direct connections between the front- and rear-side pads, passing all ports to the bottom B2B connectors. 2.7 Debugging Facilities The Starter-kit provides a JTAG-Interface on a 20-pin 2.54mm (0.1in) IDC-header for debugging. The header uses the ARM standard pin out. The second facility is an ARM-standard trace-connector. This combines the JTAG-interface with an up to 16-bit trace-port for extended debugging features. Only one connector may be used at the same time, as some signals are shared between them. Debugging requires a proper interface and corresponding software on the host system. UG-9E0005-10 - 12 - © Fujitsu Semiconductor Europe GmbH SK-MB9DF120-001 / -002 / -003 Installation 3 Installation 3.1 First Contact After opening the box, please check first if all parts are included. If any parts are missing, ask your vendor. The kit includes electrostatic sensitive devices. Unpacking should be done in an anti-static environment. After removing the packing-material, check all parts and especially the PCB for damages. Also check the jumper-settings before initial powering up the board. 3.2 Engage To power-up the board, first change the slider-switch (S1) to the “off”-position. Then connect an AC-adaptor Connect the DC-plug (inner is positive) to the board (X4), then turn on the sliderswitch. The AC-adaptor must provide 9-12V/1A min. The positive (+) supply must be on the inner tip, while the negative supply (-/GND) is on the outer ring. The power-input includes reverse-polarity protection. 3.3 Lifesigns After powering-up by turning switch S1, the power-LEDs should turn on without noticeable delay. Additionally, the reset-LED flashes once, signalling release of the reset-signal by the voltage supervisor. If no LED lights op, turn off the power switch and check the polarity of the supply. If this is ok, or if some power-LEDs are missing, flicker or show otherwise strange behaviour, check the powerrails for shorts to GND and each other before retrying. If the reset-LED flashes from time to time (maybe with a constant frequency), the power-supply may be too weak to supply the required current. Also check the voltages to detect drop. Most times this occurs, one or multiple power-rails are at the edge of the SVS' trigger-level and drop below, eg. if more current is drawn by a device. Use HDR1, 3 and 6 to measure voltages. Never short these Headers! © Fujitsu Semiconductor Europe GmbH - 13 - UG-9E0005-10 SK-MB9DF120-001 / -002 / -003 Configuration and Test-Points 4 Configuration and Test-Points 4.1 Jumpers The SK-MB9DF-120-001 provides multiple options to access signals and configure its properties. For this, it has two variants of jumpers: (regular) Jumpers consist of two or three pin-headers and a small cap. They can be changed without extra tools. They are used where changes are likely to occur. Wide jumpers (W) use a 2.54mm raster, while small jumpers use 2.00mm . The former are used for power-connections where also measuring may be required, while the latter are sole configuration jumpers. solder-jumpers change more basic options, the vast majority of applications do not require changing them from their defaults. A solder-jumper is either a single 0R0 resistor or two resistors of which only one may be placed. For the latter, a shared pad is often used to avoid placing both resistors accidentally. Name Label Description Type Default Position JP3 AVSS5 open = access ADC VRL5 (reference input) Caution: the ADC is an analog subsystem and therefore sensitive to noise induced from the power-supply lines. 2-pin wide closed top G/H-12 JP4 AVDD5 select ADC-supply: 1-2 = AVRH5 2-3 = VDP5 open = external Caution: the ADC is an analog subsystem and therefore sensitive to noise induced from the power-supply lines. 3-pin wide 2-3 top H-12 JP5 AVRH5 open = access ADC VRH5 (reference input). Caution: the ADC is an analog subsystem and therefore sensitive to noise induced from the power-supply lines. 2-pin wide closed top F/G-12 JP6 AVSS5 open = access ADC VSS. Caution: the ADC is an analog subsystem and therefore sensitive to noise induced from the power-supply lines. 2-pin wide closed top G-12 JP20 VDP5 select VDP5 supply-rail: 1-2 = 3V3 (3.3V on-board rail) 2-3 = 5V0 (5.0V on-board rail) open = external 3-pin wide 2-3 top C-5/6 JP18 DVCC select DVCC supply-rail: 1-2 = 3V3 (3.3V on-board rail) 2-3 = 5V0 (5.0V on-board rail) open = external 3-pin wide 2-3 top E-11/12 JP15 MCU_VDD open = access 1.2V supply for MCU. 2-pin wide closed top D/E-5 JP17 MCU_VDP3 open = access VDP3 domain for MCU. 2-pin wide closed top D/E-4/5 JP21 MCU_VDP5 open = access VDP5 domain for MCU. 2-pin wide closed top D/E-6 JP19 M_DVCC open = access DVCC domain for MCU. 2-pin wide closed top D/E-11/12 UG-9E0005-10 - 14 - © Fujitsu Semiconductor Europe GmbH SK-MB9DF120-001 / -002 / -003 Configuration and Test-Points Name Label Description Type Default Position JP14 TRCCHIP Select trace-signals for trace-port: 1-2 = dedicated trace-port/disable 2-3 = multiplexed ports (176pin pkg) open = none (should not be used) For the 240-pin package, there is no reason to choose any other setting than 1-2. For any package, any other than this setting also disconnects the multiplexed port-signals from their normal connection, rendering these ports unusable. Therefore, the 2-3 setting should never be chosen unless tracing with a 176-pin package is required. 3-pin small 1-2 top M/N-6/7 JP10 RTCK-sel enable/disable RTCK on JTAG: 1-2 = disable (pulled to GND) 2-3 = enable open = invalid see also solder-jumper R7 3-pin small 1-2 top J/K-12/13 JP11 TRC_RST closed = enable resets from debug and trace connector. Quite likely not to be changed. 2-pin small closed top K-12/13 JP22 SVS_EN closed = enable resets from system-voltage supervisor chip. As the SVS also monitors the reset-button, this also disables manual reset if open. Quite likely not to be changed. 2-pin small closed top K/L-5 JP27 CAN_RXD closed = connect RXD on CAN-Interface to MCU-port P2_41 2-pin small closed top M-5 JP28 CAN_TXD closed = connect TXD on CAN-Interface to MCU-port P2_40 2-pin small closed top L/M-5 JP30 UART_RXD closed = connect RXD on UART-Interface to MCU-port P0_45 2-pin small closed top P-5 JP31 UART_TXD closed = connect TXD on UART-Interface to MCU-port P0_47 2-pin small closed top P-5 closed = enable RTCK open to avoid disturbance on TCK line if RTCK is not used. If operating on lower frequencies, can be left connected if no problems arise with TCK. solder, 1R closed top G-10 (directly at 296pin footprint) R7 Table 4-1: Default Jumper settings and location On wide jumpers, the cap can be replaced by an amperemeter to measure current. However, care must be taken to avoid inducing noise into the connected cables. Alternatively, if the cap is removed, external power can be feed into the corresponding domain. Caution: do not back-drive current into the supply-rails. Check the schematics before connecting an external power-supply to a jumper's output pin (the pin which drives the power-domain). Double-check before powering up! DVCC, AVCC5 and VDP5 (see further description below) must be set to the same voltage-rail when zero point detection (ZPD) on any of the SMC ports is to be used. Check the datasheet for further requirements on the combination of voltages. © Fujitsu Semiconductor Europe GmbH - 15 - UG-9E0005-10 SK-MB9DF120-001 / -002 / -003 Configuration and Test-Points 4.2 Headers Headers are intended to access interesting nets on the PCB. They have the same sizes as wide jumpers, but may never be shortened. Name Label Description Type Position HDR1 5V0 5.0V rail voltage measuring header. Do not inject any current here! 2-pin wide top F-9 HDR2 VIN_prot Filtered and protected (against surges and reverse polarity) input voltage. May be used to inject an external supply. 2-pin wide top F-4 HDR3 3V3 3.3V rail voltage measuring header. Do not inject any current here! 2-pin wide top F-6/7 HDR4, 5 GND Access-points to the GND-plane. Can be used as reference for scopes, logic-analyzers, voltmeters, etc. 3-pin wide (each) top B-4, B-14 HDR6 1V2 1.2V rail voltage measuring header. Do not inject any current here! 2-pin wide top F-2 Table 4-2: Header location 4.3 Test Points Test points are not for permanent connection, but mostly for failure-tracking. Normally, there is no need to access them. Name Label Description Position TP1 SubClk input of 32768Hz crystal-oscillator (RTC, etc.). top H-6 TP2 MainClk MainClk frequency for variant SOCKET (Q2/Q4). top H-5/6 TP4 SYSC_CKOT MCU-port P0_41 which can have this signal multiplexed on its top F-7 output. TP5 SYSC_CKOTX MCU-port P0_42 which can have this signal multiplexed on its top F-7 output. TP6 RTC_WOT MCU-port P0_40 which can have this signal multiplexed on its top F-7 output. TP7 WDG_OBSERVE MCU-port P0_43 which can have this signal multiplexed on its top F-7 output. Table 4-3: Test point location The crystal test points TP1-3 are very sensitive to noise and load-factors, especially capacitive loads can change the frequency dramatically. If possible, the clocks should be measured indirectly using a high-speed timer or SYSC_CKOT. UG-9E0005-10 - 16 - © Fujitsu Semiconductor Europe GmbH FUJITSU MIKROELEKTRONIK GmbH Status Display 5 Status Display For user information, there are four LEDs on the board. Each power-rail (the supply generated on-board), is monitored by a single LED. In addition, the reset-LED shows the status of the reset-line. For the default configuration and no external reset (JTAG, button or from a plugged-under PCB), this is the status of the systemvoltage supervisor (SVS). It will be lit if any voltage-rail is out of its allowed limits. Name Label Description (when lit) Position LD1 orange 5V0 rail up top E-2 LD2 yellow 3V3 rail up top E-2 LD3 green 1V2 rail up (driven by 3V3-rail) top F-2 LD4 red reset active Table 5-1: LED position and meaning top F-2 © Fujitsu Semiconductor Europe GmbH - 17 - UG-9E0005-10 SK-MB9DF120-001 / -002 / -003 Connectors 6 Connectors The following table lists the location of all connectors on the board. The pin-out of each connector is listed in separate sections. Name Type Description Position J5 SAMTEC QSH090-01-L-D-A board-to-board connector. Allows to connect a Multi-IO Bottom board or any other matching I/O-board. Q-4:13 J6 SAMTEC QSH090-01-L-D-A B2B, Further signals from the MCU. X2 Standard ARM 20pin debug-header with JTAG2*10 2.54mm IDC interface. Must not be connected at the same time as header (male) X3. X3 38pin connector for standard ARM trace interface (16 TYCO 5767054-1 bits). Includes also JTAG. Must not be connected at top K:O-14 the same time as X2. X6 SAMTEC MEC617002SDVA 2*70pin card-edge connector for Riser-Board. Used for high-speed interfaces like QSPI-Flash and/or SDRAM. top O-5:12 Can also be used for custom extensions requiring the external bus of the MCU. X4 DC-plug 2.1mm pin DC plug for external power-supply. top C-14:16 X5 9pin Dsub male CAN-Bus connector with standard-pinout. top J:N-1:3 X7 USB Mini-B plug Standard USB plug to connect a PC whith USB-Serial top P-2 protocol driver. Bottom B-4:13 top K:O-16 Table 6-1: Connector location The two B2B connectors provide all MCU ports, power supplies and control-signals. UG-9E0005-10 - 18 - © Fujitsu Semiconductor Europe GmbH SK-MB9DF120-001 / -002 / -003 Connectors 6.1 B2B Connectors (J5, J6) These two connectors provide all signals to a plug-under board like the Multi-IO-Board. Signals include all MCU ports as well as reset and power supplies from the SK-board. Signals are always routed to these connectors, even if they are used on the SK-MB9DF125-001 themselves. When using a signal on a plug-under board which is also connected to an on-board peripheral or connector (like the IPC-connector), it must be disconnected from the on-board resource by pulling the corresponding jumper. Some signals can be disconnected separately, while other signals are disconnected as a whole function-block. Fitting mates for the other board are SAMTEC QTH type connectors. 6.1.1 Connector J5 Pinout Special Signals Pin(s) Signal Description 1,2,6,7,12,13,54,55, 65,66,97,98,101,102,109,110,113, 137,138,162,167,171,172, Shield GND System Ground 3-5,8-11,14-53,99,100,112,119 n.c. not connected 103,105,107 reserved do not use 104,106,108 VDP5 VDP5 power domain 164,166,168,170 5V0 5.0V power rail 173,175,177,179 Vin Raw input power (after the power-switch, but before any filter/protection. Should not be used. 174, 176, 178, 180 Vin_prot Vin after the filter. May be used to supply SKMB9DF125 from a plug-under board. 169 RST_X_VDP5 System-Reset. Open-Collector (pull-up on SK-MB9DF125). input/output Table 6-2: J5 power supply pins MCU-Ports ADA-FCR4-MULTIIO-001 Signal MCU Port J5 Pin J5 Pin MCU Port ADA-FCR4-MULTIIO-001 Signal GND - 55 56 P0_26 GPIO0 UARTB_RX P0_40 57 58 P0_45 UARTA_RX UARTB_TX P0_42 59 60 P0_47 UARTA_TX CANB_RX P2_45 61 62 P2_41 CANA_RX CANB_TX P2_44 63 64 P2_40 CANA_TX GND - 65 66 - GND EXTN2_GPIO00 R_P3_0 67 68 R_P3_1 EXTN2_GPIO01 EXTN2_GPIO02 R_P3_2 69 70 R_P3_3 EXTN2_GPIO03 EXTN2_GPIO04 R_P3_4 71 72 R_P3_5 EXTN2_GPIO05 EXTN2_GPIO06 R_P3_6 73 74 R_P3_7 EXTN2_GPIO07 EXTN2_GPIO08 R_P3_8 75 76 R_P3_9 EXTN2_GPIO09 © Fujitsu Semiconductor Europe GmbH - 19 - UG-9E0005-10 SK-MB9DF120-001 / -002 / -003 Connectors ADA-FCR4-MULTIIO-001 Signal MCU Port J5 Pin J5 Pin MCU Port ADA-FCR4-MULTIIO-001 Signal EXTN2_GPIO10 R_P3_10 77 78 R_P3_11 EXTN2_GPIO11 EXTN2_GPIO12 R_P3_12 79 80 R_P3_13 EXTN2_GPIO13 EXTN2_GPIO14 R_P3_14 81 82 R_P3_15 EXTN2_GPIO15 EXTN2_GPIO16 R_P3_16 83 84 R_P3_17 EXTN2_GPIO17 EXTN2_GPIO18 R_P3_18 85 86 R_P3_19 EXTN2_GPIO19 EXTN2_GPIO20 R_P3_20 87 88 R_P3_21 EXTN2_GPIO21 EXTN2_GPIO22 R_P3_22 89 90 R_P3_23 EXTN2_GPIO23 EXTN2_GPIO24 R_P3_24 91 92 R_P3_25 EXTN2_GPIO25 EXTN2_GPIO26 R_P3_26 93 94 R_P3_27 EXTN2_GPIO27 EXTN2_GPIO28 R_P3_28 95 96 R_P3_29 EXTN2_GPIO29 GND - 97 98 - GND GPIO1 P0_27 99 100 P0_28 GPIO2 GND - 101 102 - GND P_1V2 - 103 104 - VDP5 P_1V2 - 105 106 - VDP5 P_1V2 - 107 108 - VDP5 GND - 109 110 - GND POTI_AN P0_44 111 112 NC SOUND_SGA GND - 113 114 P2_47 SOUND_SGO CLUSTER_EXT_INT0 P0_46 115 116 P2_36 CLUSTER_PWM0 CLUSTER_EXT_INT1 P2_39 117 118 P2_37 CLUSTER_PWM1 GPIO3 NC 119 120 P2_38 CLUSTER_PWM2 CLUSTER_SMC00 P1_0 121 122 P1_4 CLUSTER_SMC10 CLUSTER_SMC01 P1_1 123 124 P1_5 CLUSTER_SMC11 CLUSTER_SMC02 P1_2 125 126 P1_6 CLUSTER_SMC12 CLUSTER_SMC03 P1_3 127 128 P1_7 CLUSTER_SMC13 CLUSTER_SMC20 P1_8 129 130 P1_12 CLUSTER_SMC30 CLUSTER_SMC21 P1_9 131 132 P1_13 CLUSTER_SMC31 CLUSTER_SMC22 P1_10 133 134 P1_14 CLUSTER_SMC32 CLUSTER_SMC23 P1_11 135 136 P1_15 CLUSTER_SMC33 GND - 137 138 - GND CLUSTER_GPIO0 P0_41 139 140 P0_8 LED0 CLUSTER_GPIO1 P0_43 141 142 P0_9 LED1 CLUSTER_GPIO2 P2_42 143 144 P0_10 LED2 CLUSTER_GPIO3 P2_43 145 146 P0_11 LED3 CLUSTER_GPIO4 P2_46 147 148 P0_12 LED4 CLUSTER_GPIO5 P1_16 149 150 P0_13 LED5 UG-9E0005-10 - 20 - © Fujitsu Semiconductor Europe GmbH SK-MB9DF120-001 / -002 / -003 Connectors ADA-FCR4-MULTIIO-001 Signal MCU Port J5 Pin J5 Pin MCU Port ADA-FCR4-MULTIIO-001 Signal CLUSTER_GPIO6 P1_17 151 152 P0_14 LED6 CLUSTER_GPIO7 P1_18 153 154 P0_15 LED7 CLUSTER_GPIO8 P1_19 155 156 P0_48 BUTTON_EXT_INT0 CLUSTER_GPIO9 P1_20 157 158 P0_49 BUTTON_EXT_INT1 CLUSTER_GPIO10 P1_21 159 160 P0_50 BUTTON_EXT_INT2 CLUSTER_GPIO11 P1_22 161 162 - GND CLUSTER_GPIO12 P1_23 163 164 - P_5V BUTTON_EXT_INT3 P0_51 165 166 - P_5V GND - 167 168 - P_5V BOARD_RST_X - 169 170 - P_5V GND - 171 172 - GND P_12V - 173 174 - P_12V_P P_12V - 175 176 - P_12V_P P_12V - 177 178 - P_12V_P P_12V - 179 180 - P_12V_P Table 6-3: J5 signal assignment Signals R_P* are indirect connections. They come from the “output”-side of the Riser-Board, thus are not connected anywhere unless the Riser-Board connects them the corresponding MCU-port. The numbering used here is for a standard Riser-Board (MEM-FCR4-001) which connects all MCU-ports to the adjacent “output” R_P*-signal without any crossover. For other Riser-Boards, some to all of the R_P*-signals are not available (unconnected). Although possible, a Riser-Board should not pass an input-port from the MCU on a different R_P*-signal. 6.1.2 Connector J6 Pinout Special Signals Pin(s) Signal Description 5,6,25,26,31,32,37,38,46,47,51,52, 65,66,71,72,77,78,83,84,,89,90,95,96, 100,101,114,115, 125,126,131,132,137,138,143,144,149 ,150,155,156,160-162,175,176, Shield GND System Ground 7-24,33-36,41-44,53-60, 61-64,67-70,73-76,79-82,85-88,9194,97,99,103,105,107, 121-124,127-130,133-136,139142,145-148,151-154,157-159,163168,170,172-174 n.c. not connected 1-4,177-180 3V3 3.3V power rail. Table 6-4: J6 power supply pins © Fujitsu Semiconductor Europe GmbH - 21 - UG-9E0005-10 SK-MB9DF120-001 / -002 / -003 Connectors MCU-Ports ADA-FCR4-MULTIIO-001 Signal MCU Port Pin J6 Pin J6 Pin MCU Port Pin ADA-FCR4-MULTIIO-001 Signal I2SA_ECLK P2_32 27 28 P2_35 I2SA_SCK I2SA_SD P2_33 29 30 P2_34 I2SA_WS GND - 31 32 - GND I2SB_ECLK NC 33 34 NC I2SB_SCK I2SB_SD NC 35 36 NC I2SB_WS GND - 37 38 - GND I2CA_SDA P0_63 39 40 P0_62 I2CA_SCL I2CC_SDA NC 41 42 NC I2CB_SCL P3V3_EXT_INT2 NC 43 44 NC I2CC_SCL P3V3_EXT_INT2 R_P3_32 45 46 - GND GND - 47 48 R_P3_41 P3V3_EXT_INT0 CAP_CLK NC 49 50 R_P3_42 P3V3_EXT_INT1 GND - 51 52 - GND CAP_VI0 NC 53 54 NC CAP_VI1 CAP_VI2 NC 55 56 NC CAP_VI3 CAP_VI4 NC 57 58 NC CAP_VI5 CAP_VI6 NC 59 60 NC CAP_VI7 DISP1_R0 NC 61 62 NC DISP1_R2 DISP1_R1 NC 63 64 NC DISP1_R3 GND - 65 66 - GND DISP1_R4 NC 67 68 NC DISP1_R6 DISP1_R5 NC 69 70 NC DISP1_R7 GND - 71 72 - GND DISP1_G0 NC 73 74 NC DISP1_G2 DISP1_G1 NC 75 76 NC DISP1_G3 GND - 77 78 - GND DISP1_G4 NC 79 80 NC DISP1_G6 DISP1_G5 NC 81 82 NC DISP1_G7 GND - 83 84 - GND DISP1_B0 NC 85 86 NC DISP1_B2 DISP1_B1 NC 87 88 NC DISP1_B3 GND - 89 90 - GND DISP1_B4 NC 91 92 NC DISP1_B6 DISP1_B5 NC 93 94 NC DISP1_B7 GND - 95 96 - GND UG-9E0005-10 - 22 - © Fujitsu Semiconductor Europe GmbH SK-MB9DF120-001 / -002 / -003 Connectors ADA-FCR4-MULTIIO-001 Signal MCU Port Pin J6 Pin J6 Pin MCU Port Pin ADA-FCR4-MULTIIO-001 Signal DISP1_DCLK NC 97 98 R_P1_24 DISP1_DCLKI DISP1_DISP25 NC 99 100 - GND GND - 101 102 R_P1_25 DISP1_TSIG6 DISP1_HSYNC NC 103 104 R_P1_26 DISP1_TSIG7 DISP1_VSYNC NC 105 106 R_P1_27 DISP1_TSIG8 DISP1_DE NC 107 108 R_P1_28 DISP1_TSIG9 DISP1_TSIG3 R_P1_29 109 110 R_P1_30 DISP1_TSIG10 DISP1_TSIG4 R_P1_31 111 112 R_P1_32 DISP1_TSIG11 DISP1_TSIG5 R_P1_33 113 114 - GND GND - 115 116 R_P1_34 P3V3_GPIO00 P3V3_GPIO03 R_P1_35 117 118 R_P1_36 P3V3_GPIO01 P3V3_GPIO04 R_P1_37 119 120 R_P1_38 P3V3_GPIO02 DISP0_R0 NC 121 122 NC DISP0_R2 DISP0_R1 NC 123 124 NC DISP0_R3 GND - 125 126 - GND DISP0_R4 NC 127 128 NC DISP0_R6 DISP0_R5 NC 129 130 NC DISP0_R7 GND - 131 132 - GND DISP0_G0 NC 133 134 NC DISP0_G2 DISP0_G1 NC 135 136 NC DISP0_G3 GND - 137 138 - GND DISP0_G4 NC 139 140 NC DISP0_G6 DISP0_G5 NC 141 142 NC DISP0_G7 GND - 143 144 - GND DISP0_B0 NC 145 146 NC DISP0_B2 DISP0_B1 NC 147 148 NC DISP0_B3 GND - 149 150 - GND DISP0_B4 NC 151 152 NC DISP0_B6 DISP0_B5 NC 153 154 NC DISP0_B7 GND - 155 156 - GND DISP0_DCLK NC 157 158 R_P3_40 DISP0_DCLKI DISP0_DISP25 NC 159 160 - GND GND - 161 162 - GND DISP0_HSYNC NC 163 164 R_P3_34 DISP0_TSIG6 DISP0_VSYNC NC 165 166 R_P3_35 DISP0_TSIG7 DISP0_DE NC 167 168 R_P3_36 DISP0_TSIG8 DISP0_TSIG3 R_P3_30 169 170 R_P3_37 DISP0_TSIG9 © Fujitsu Semiconductor Europe GmbH - 23 - UG-9E0005-10 SK-MB9DF120-001 / -002 / -003 Connectors ADA-FCR4-MULTIIO-001 Signal MCU Port Pin J6 Pin J6 Pin MCU Port Pin ADA-FCR4-MULTIIO-001 Signal DISP0_TSIG4 R_P3_31 171 172 R_P3_38 DISP0_TSIG10 DISP0_TSIG5 R_P3_33 173 174 R_P3_39 DISP0_TSIG11 GND - 175 176 - GND P_3V3 - 177 178 - P_3V3 P_3V3 - 179 180 - P_3V3 Table 6-5: J6 signal assignment Signals R_P* are indirect connections. They come from the “output”-side of the Riser-Board, thus are not connected anywhere unless the Riser-Board connects them the corresponding MCU-port. The numbering used here is for a standard Riser-Board (MEM-FCR4-001) which connects all MCU-ports to the adjacent “output” R_P*-signal without any crossover. For other Riser-Boards, some to all of the R_P*-signals are not available (unconnected). Although possible, a Riser-Board should not pass an input-port from the MCU on a different R_P*-signal. 6.2 Debug Connector (X2) This is an ARM standard 20 pin JTAG connector. Pin Signal Description 1 Vsns Target voltage reference 2 VCCt Target power 3 nTRST JTAG TAP reset, active low 4 GND Ground 5 TDI JTAG Test Data In 6 GND Ground 7 TMS JTAG Test Machine State 8 GND Ground 9 TCK JTAG TAP Clock 10 GND Ground 11 RTCK Return TCK (optional) 12 GND Ground 13 TDO JTAG Test Data Out 14 GND Ground 15 nRESET Target reset, active low (system reset) 16 GND Ground 17 DBREQ Debug Request (not used) 18 GND Ground 19 TVcc Debug Acknowledge (not used) 20 GND Ground Table 6-6: Debug connector (X2) assignment UG-9E0005-10 - 24 - © Fujitsu Semiconductor Europe GmbH SK-MB9DF120-001 / -002 / -003 Connectors RTCK is deactivated by jumpers by default. It is only required for high-speed clocking. See jumper-settings on how to enable this functionality. This connector must not be used at the same time as the trace-connector. 6.3 Trace Connector (X3) Much like the Debug-connector, this is also defined by ARM. Pin Signal Description 1-4, 10 NC No connection 5, 30, 32 GND Signal Ground 14, 34 VSUPPLY Voltage Supply pin 12 VTREF Target reference voltage 6 TRACECLK Trace Clock pin 7 DBREQ Probe Debug Request (unused) 8 DBACK Probe Debug Acknowledge (unused) 9 nRESET Target reset, active low 11 TDO JTAG Test Data Out 13 RTCK JTAG Return TCK (optional) 15 TCK JTAG TAP Clock 16 TRACE7 Trace data 17 TMS JTAG Test Machine State 18 TRACE6 Trace data 19 TDI JTAG Test Data In 20 TRACE5 Trace data 21 nTRST JTAG TAP Reset, active low 22 TRACE4 Trace data 23 TRACE15 Trace data 24 TRACE3 Trace data 25 TRACE14 Trace data 26 TRACE2 Trace data 27 TRACE13 Trace data 28 TRACE1 Trace data 29 TRACE12 Trace data 31 TRACE11 Trace data 33 TRACE10 Trace data 35 TRACE9 Trace data 36 TRACECTL Trace Control 37 TRACE8 Trace data 38 TRACE0 Trace data Table 6-7: Trace connector (X3) assignment © Fujitsu Semiconductor Europe GmbH - 25 - UG-9E0005-10 SK-MB9DF120-001 / -002 / -003 Connectors For the JTAG-signals see section 6.3 for details. Trace-width is 16 bit for the 296-pin package. For the 176-pin package, 8 MCU port-lines can be connected to the trace-port using a jumper. As this disconnects the signals from their normal interface, it is possible to trace the MCU while still having the external connections. However, the signals will not pass to the MCU, of course. This connector must not be used at the same time as the debug-connector. 6.4 Riser-Board Connector (X6) This is a card-edge connector. It includes al signals related to the external bus-interface of the MB96DF125 (Atlas-L) and the high-speed QSPI signals. Also included are the necessary 3.3V power supply and the (3V3) reset-signal. This connector allows to connect high-speed devices either to the HSSPI (serial QSPI-Flash) or external bus (SDRAM, NAND-Flash, external Ethernetcontroller, etc.). Ports not used for a particular Riser-Board application can be connected to the adjacent pad routed to the b2b connector, allowing to use this signal otherwise. Signal Riser pad Pin Pin Riser Pad Signal 3V3 A1 1 2 B1 GND 3V3 A2 3 4 B2 GND 3V3 A3 5 6 B3 RST_X_3V3 3V3 A4 7 8 B4 GND R_P1_34 A5 9 10 B5 P1_34 R_P1_35 A6 11 12 B6 P1_35 R_P1_36 A7 13 14 B7 P1_36 R_P1_37 A8 15 16 B8 P1_37 R_P1_38 A9 17 18 B9 P1_38 R_P1_30 A10 19 20 B10 P1_30_B R_P1_31 A11 21 22 B11 P1_31_B R_P1_32 A12 23 24 B12 P1_32_B R_P1_33 A13 25 26 B13 P1_33_B R_P3_0 A14 27 28 B14 P3_0 R_P3_1 A15 29 30 B15 P3_1 R_P3_2 A16 31 32 B16 P3_2 GND A17 33 34 B17 GND R_P3_3 A18 35 36 B18 P3_3 R_P3_4 A19 37 38 B19 P3_4 R_P3_5 A20 39 40 B20 P3_5 R_P3_6 A21 41 42 B21 P3_6 R_P3_7 A22 43 44 B22 P3_7 R_P3_8 A23 45 46 B23 P3_8 R_P3_9 A24 47 48 B24 P3_9 R_P3_10 A25 49 50 B25 P3_10 UG-9E0005-10 - 26 - © Fujitsu Semiconductor Europe GmbH SK-MB9DF120-001 / -002 / -003 Connectors Signal Riser pad Pin Pin Riser Pad Signal R_P3_11 A26 51 52 B26 P3_11 R_P3_12 A27 53 54 B27 P3_12 R_P1_24 A28 55 56 B28 P1_24_B R_P1_25 A29 57 58 B29 P1_25_B GND A30 59 60 B30 GND R_P3_33 A31 61 62 B31 P3_33 R_P3_34 A32 63 64 B32 P3_34 R_P3_35 A33 65 66 B33 P3_35 R_P3_36 A34 67 68 B34 P3_36 R_P3_37 A35 69 70 B35 P3_37 R_P3_38 A36 71 72 B36 P3_38 R_P3_39 A37 73 74 B37 P3_39 R_P3_40 A38 75 76 B38 P3_40 R_P3_41 A39 77 78 B39 P3_41 R_P3_42 A40 79 80 B40 P3_42 R_P3_13 A41 81 82 B41 P3_13 R_P3_14 A42 83 84 B42 P3_14 GND A43 85 86 B43 GND R_P3_15 A44 87 88 B44 P3_15 R_P3_16 A45 89 90 B45 P3_16 R_P3_17 A46 91 92 B46 P3_17 R_P3_18 A47 93 94 B47 P3_18 R_P3_19 A48 95 96 B48 P3_19 R_P3_20 A49 97 98 B49 P3_20 R_P3_21 A50 99 100 B50 P3_21 R_P3_22 A51 101 102 B51 P3_22 R_P3_23 A52 103 104 B52 P3_23 R_P3_24 A53 105 106 B53 P3_24 R_P3_25 A54 107 108 B54 P3_25 R_P3_26 A55 109 110 B55 P3_26 GND A56 111 112 B56 GND R_P3_27 A57 113 114 B57 P3_27 R_P3_28 A58 115 116 B58 P3_28 R_P3_29 A59 117 118 B59 P3_29 R_P3_30 A60 119 120 B60 P3_30 R_P3_31 A61 121 122 B61 P3_31 R_P3_32 A62 123 124 B62 P3_32 R_P1_26 A63 125 126 B63 P1_26_B © Fujitsu Semiconductor Europe GmbH - 27 - UG-9E0005-10 SK-MB9DF120-001 / -002 / -003 Connectors Signal Riser pad Pin Pin Riser Pad Signal R_P1_27 A64 127 128 B64 P1_27_B R_P1_28 A65 129 130 B65 P1_28_B R_P1_29 A66 131 132 B66 P1_29_B 3V3 A67 133 134 B67 3V3 3V3 A68 135 136 B68 3V3 3V3 A69 137 138 B69 3V3 3V3 A70 139 140 B70 3V3 Table 6-8: Riser-Board Connector (X6) assignment The “Riser-Pad” column in the table above lists the name of the corresponding pad on the cardedge riser-card (these use A or B for top/bottom layer and linear numbering on each side). The R_P*-signals adjacent to the corresponding MCU-port. They are intended to be connected directly to the MCU-signal if not used on the Riser-Board. The default Riser-Board which ships with the SK-MB9DF125 has no active devices on it, so it passes all ports through. Signals ending with “_B” are passed thru a limiting switch. They may be used as trace-signals (only useful for the 176pin package). If so, they are disconnected from the Riser-Board, rendering bus-functions requiring these signals unusable. 6.5 DC In Plug (X4) The following figure shows the power connection plug. This connector is used to connect an external DC power supply with 12V/1.5A DC to the evaluation board. Observe the polarity of the power-supply lines. UG-9E0005-10 - 28 - © Fujitsu Semiconductor Europe GmbH SK-MB9DF120-001 / -002 / -003 Connectors 6.6 CAN-Bus Connector (X5) This is a standard pin-out used for industrial CAN. Pin Signal Description 1 NC Not used 2 CANL default low CAN-bus signal (inverted differential line) 3 GND Ground 4 NC Not used 5 NC Not used 6 NC Not used 7 CANH default high CAN-bus signal (non-inverted differential line) 8 NC Not used 9 NC Not used Shield Shield Tied to GND via 1M0||100nF Table 6-9: Can Bus Connector (X5) assignment Check jumpers when using CAN to have the signals connected to the bus-driver. Also make sure the related ports are not connected elsewhere via the B2B connectors. 6.7 USB Connector (X7) Standard USB Mini-B Plug. Pin Signal Description 1 VBUS +5.0V Supply from Host. Powers the USB/Serial Converter FT232R 2 D- inverted data-line 3 D+ non-inverted data-line 4 ID leave open 5 GND Reference-voltage Shield Shield Tied to GND via 1M0||100nF Table 6-10: USB Connector (X7) assignment Check jumpers when using USB/UART to have the signals connected to the bus-driver. Also make sure the related ports are not connected elsewhere via the B2B connectors. © Fujitsu Semiconductor Europe GmbH - 29 - UG-9E0005-10 SK-MB9DF120-001 / -002 / -003 Known Issues 7 Known Issues UG-9E0005-10 - 30 - © Fujitsu Semiconductor Europe GmbH SK-MB9DF120-001 / -002 / -003 Trouble shooting 8 Trouble shooting © Fujitsu Semiconductor Europe GmbH - 31 - UG-9E0005-10 SK-MB9DF120-001 / -002 / -003 Related Products 9 Related Products EMA-MB9DF125-001 MB96DF125 (Atlas-L) Emulation Adapter MEM-FCR4-004 2 MB SRAM and 16 MB NOR Flash Memory Extension Board ADA-FCR4-MULTIIO-001 Base board for using of MCU board with several IO interfaces like CAN, LIN, MediaLB, Ethernet, Video and Audio accessing ADA-FCR4-CLUSTER-001 Automobile dashboard sample with stepper-motors and other functions. UG-9E0005-10 - 32 - © Fujitsu Semiconductor Europe GmbH SK-MB9DF120-001 / -002 / -003 Appendix 10 Appendix 10.1 Tables Table 4-1: Default Jumper settings and location................................................................... 15 Table 4-2: Header location ................................................................................................... 16 Table 4-3: Test point location ............................................................................................... 16 Table 5-1: LED position and meaning .................................................................................. 17 Table 6-1: Connector location .............................................................................................. 18 Table 6-2: J5 power supply pins ........................................................................................... 19 Table 6-3: J5 signal assignment ........................................................................................... 21 Table 6-4: J6 power supply pins ........................................................................................... 21 Table 6-5: J6 signal assignment ........................................................................................... 24 Table 6-6: Debug connector (X2) assignment ...................................................................... 24 Table 6-7: Trace connector (X3) assignment ....................................................................... 25 Table 6-8: Riser-Board Connector (X6) assignment ............................................................. 28 Table 6-9: Can Bus Connector (X5) assignment .................................................................. 29 Table 6-10: USB Connector (X7) assignment ...................................................................... 29 10.2 Figures Figure 2-1: Top View PCB-Rev.1.0 ........................................................................................ 8 Figure 2-2: Bottom View PCB-Rev.1.0 ................................................................................... 9 © Fujitsu Semiconductor Europe GmbH - 33 - UG-9E0005-10 SK-MB9DF120-001 / -002 / -003 Information in the WWW 11 Information in the WWW Information about FUJITSU SEMICONDUCTOR Products can be found on the following Internet pages: Microcontrollers (8-, 16- and 32bit), Graphics Controllers Datasheets and Hardware Manuals, Support Tools (Hard- and Software) http://mcu.emea.fujitsu.com/ Power Management Products http://www.fujitsu.com/emea/services/microelectronics/powerman/index.html For more information about FUJITSU SEMICONDUCTOR http://emea.fujitsu.com/semiconductor UG-9E0005-10 - 34 - © Fujitsu Semiconductor Europe GmbH SK-MB9DF120-001 / -002 / -003 EU-Konformitätserklärung / EU declaration of conformity 12 EU-Konformitätserklärung / EU declaration of conformity Hiermit erklären wir, Fujitsu Semiconductor Europe GmbH, Pittlerstrasse 47, 63225 Langen, Germany dass dieses Board aufgrund seiner Konzipierung und Bauart sowie in den von uns in Verkehr gebrachten Ausführung(en) den grundlegenden Anforderungen der EU-Richtlinie 2004/108/EC „Elektromagnetische Verträglichkeit“ entspricht. Durch eine Veränderung des Boards (Hard- und/ oder Software) verliert diese Erklärung ihre Gültigkeit! We, Fujitsu Semiconductor Europe GmbH, Pittlerstrasse 47, 63225 Langen, Germany hereby declare that the design, construction and description circulated by us of this board complies with the appropriate basic requirements according to the EU Guideline 2004/108/EC entitled ’Electro-Magnetic Compatibility’. Any changes to the equipment (hardware and/ or software) will render this declaration invalid! Note: All data and power supply lines connected to this starter kit should be kept as short as possible, with a maximum allowable length of 3m. Shielded cables should be used for data lines. As a rule of thumb, the cable length used when connecting external circuitry to the MCU pin header connectors for example should be less than 20cm. Longer cables may affect EMC performance and cause radio interference. This evaluation board is a Class A product according to EN61326-1. It is intended to be used only in a laboratory environment and might cause radio interference when used in residential areas. In this case, the user must take appropriate measures to control and limit electromagnetic interference. © Fujitsu Semiconductor Europe GmbH - 35 - UG-9E0005-10 SK-MB9DF120-001 / -002 / -003 China-RoHS regulation 13 China-RoHS regulation This board is compliant with China RoHS. UG-9E0005-10 - 36 - © Fujitsu Semiconductor Europe GmbH SK-MB9DF120-001 / -002 / -003 Recycling 14 Recycling Gültig für EU-Länder: Gemäß der Europäischen WEEE-Richtlinie und deren Umsetzung in landesspezifische Gesetze nehmen wir dieses Gerät wieder zurück. Zur Entsorgung schicken Sie das Gerät bitte an die folgende Adresse: Fujitsu Semiconductor Europe GmbH Warehouse/Disposal Monzastraße 4a D-63225 Langen Valid for European Union Countries: According to the European WEEE-Directive and its implementation into national laws we take this device back. For disposal please send the device to the following address: Fujitsu Semiconductor Europe GmbH Warehouse/Disposal Monzastraße 4a D-63225 Langen GERMANY -- END -- © Fujitsu Semiconductor Europe GmbH - 37 - UG-9E0005-10