C8 0 5 1 F5 5 x / 5 6 x / 57x C8051F560 D E V E L O P M E N T K I T U SER ' S G UIDE 1. Relevant Devices The C8051F560 Development Kit is intended as a development platform for the microcontrollers in the C8051F55x/56x/57x MCU family. The target board included in this kit is provided with a pre-soldered C8051F568 MCU (QFN40 package) and a C8051F550 MCU (QFN24 package). Code developed on the C8051F568 can be easily ported to the other members of this MCU family. Refer to the C8051F55x/56x/57x data sheet for the differences between the members of this MCU family. 2. Kit Contents The C8051F560 Development Kit contains the following items: C8051F560 Target Board C8051Fxxx Development Kit Quick-Start Guide AC to DC Power Adapter USB Debug Adapter Two USB Cables 3. Hardware Setup Refer to Figure 1 for a diagram of the hardware configuration. 1. Connect the USB Debug Adapter to the DEBUG A connector on the target board with the 10-pin ribbon cable. 2. Connect one end of the USB cable to the USB connector on the USB Debug Adapter. 3. Verify that shorting blocks are installed on the target board as shown in Figure 5 on page 7. 4. Connect the other end of the USB cable to a USB Port on the PC. 5. Connect the ac/dc power adapter to power jack P4 on the target board. J16 DEBUG_B RESET_B J15 Port_2 "B" P3 www.silabs.com Power Run USB Cable Stop DEBUG_A J1 P2 Silicon Laboratories USB DEBUG ADAPTER TB3 P4 J21 RESET_A J18 J19 Port_2 "A" AC/DC Adapter J7 J10 C8051 F568 DS2 P1.3_A P1.4_A U1 SIDE "A" J4 J23 J3 DS4 CP 2102 R27 J20 CAN Port_3 "A" J2 +LIN_V P5 DS3 J9 PWR LED J24 J22 J14 LIN_OUT COMM PC SILICON LABS J17 GND LIN J0 Port_1 "A" J8 TB2 CAN_H TB1 P1.3_B DS1 C8051F560-TB U2 GND CAN_L J5 F550 CAN P1 Port_0 "A" P1.4_B J13 J11 J6 Port_1 "B" Port_0 "B" J12 LIN SIDE "B" Target Board USB Debug Adapter Figure 1. Hardware Setup using a USB Debug Adapter Rev. 0.2 6/15 Copyright (c) 2015 by Silicon Laboratories C8051F55x/56x/57x C8051F55x/56x/57x Notes: Use the Reset icon in the IDE to reset the target when connected during a debug session. Remove power from the target board and the USB Debug Adapter before connecting or disconnecting the ribbon cable from the target board. Connecting or disconnecting the cable when the devices have power can damage the device and/or the USB Debug Adapter. 4. Software Setup Simplicity Studio greatly reduces development time and complexity with Silicon Labs EFM32 and 8051 MCU products by providing a high-powered IDE, tools for hardware configuration, and links to helpful resources, all in one place. Once Simplicity Studio is installed, the application itself can be used to install additional software and documentation components to aid in the development and evaluation process. Figure 2. Simplicity Studio The following Simplicity Studio components are required for the C8051F560 Development Kit: 8051 Products Part Support Simplicity Developer Platform Download and install Simplicity Studio from www.silabs.com/8bit-software or www.silabs.com/simplicity-studio. Once installed, run Simplicity Studio by selecting StartSilicon LabsSimplicity StudioSimplicity Studio from the start menu or clicking the Simplicity Studio shortcut on the desktop. Follow the instructions to install the software, and click Simplicity IDE to launch the IDE. The first time the project creation wizard runs, the Setup Environment wizard will guide the user through the process of configuring the build tools and SDK selection. In the Part Selection step of the wizard, select from the list of installed parts only the parts to use during 2 Rev. 0.2 C8051F55x/56x/57x development. Choosing parts and families in this step affects the displayed or filtered parts in the later device selection menus. Choose the C8051F55x/56x/57x family by checking the C8051F55x/56x/57x check box. Modify the part selection at any time by accessing the Part Management dialog from the WindowPreferencesSimplicity StudioPart Management menu item. Simplicity Studio can detect if certain toolchains are not activated. If the Licensing Helper is displayed after completing the Setup Environment wizard, follow the instructions to activate the toolchain. 4.1. Running Blinky Each project has its own source files, target configuration, SDK configuration, and build configurations such as the Debug and Release build configurations. The IDE can be used to manage multiple projects in a collection called a workspace. Workspace settings are applied globally to all projects within the workspace. This can include settings such as key bindings, window preferences, and code style and formatting options. Project actions, such as build and debug are context sensitive. For example, the user must select a project in the Project Explorer view in order to build that project. To create a project based on the Blinky example: 1. Click the Software Examples tile from the Simplicity Studio home screen. 2. In the Kit drop-down, select C8051F560 Development Kit, in the Part drop-down, select C8051F560, and in the SDK drop-down, select the desired SDK. Click Next. 3. Select Example and click Next. 4. Under C8051F560 Development Kit, select F55x-57x Blinky, click Next, and click Finish. 5. Click on the project in the Project Explorer and click Build, the hammer icon in the top bar. Alternatively, go to ProjectBuild Project. 6. Click Debug to download the project to the hardware and start a debug session. 7. Press the Resume button to start the code running. The LED should blink. 8. Press the Suspend button to stop the code. 9. Press the Reset the device button to reset the target MCU. 10. Press the Disconnect button to return to the development perspective. 4.2. Simplicity Studio Help Simplicity Studio includes detailed help information and device documentation within the tool. The help contains descriptions for each dialog window. To view the documentation for a dialog, click the question mark icon in the window: This will open a pane specific to the dialog with additional details. The documentation within the tool can also be viewed by going to HelpHelp Contents or HelpSearch. Rev. 0.2 3 C8051F55x/56x/57x 4.3. CP210x USB to UART VCP Driver Installation The Target Board includes a Silicon Labs CP210x USB-to-UART Bridge Controller. Device drivers for the CP210x need to be installed before the PC software can communicate with the MCU through the UART interface. 1. After opening Simplicity Studio for the first time, a dialog will prompt to install the CP210x drivers. Click Yes. The drivers can also be installed at any time by going to HelpInstall DriversCP210x VCP USB Drivers. 2. Accept the license agreement and follow the steps to install the driver on the system. The installer will let you know when your system is up to date. The driver files included in this installation have been certified by Microsoft. 3. To complete the installation process, connect the included USB cable between the host computer and the USB connector (P5) on the Target Board. Windows will automatically finish the driver installation. Information windows will pop up from the taskbar to show the installation progress. 4. If needed, the driver files can be uninstalled by selecting Windows Driver Package--Silicon Laboratories... option in the Programs and Features window. 4.4. Configuration Wizard 2 The Configuration Wizard 2 is a code generation tool for all of the Silicon Labs devices. Code is generated through the use of dialog boxes for each of the device's peripherals. Figure 3. Configuration Wizard 2 Utility The Configuration Wizard 2 utility helps accelerate development by automatically generating initialization source code to configure and enable the on-chip resources needed by most design projects. In just a few steps, the wizard creates complete startup code for a specific Silicon Labs MCU. The program is configurable to provide the output in C or assembly. For more information, please refer to the Configuration Wizard 2 help available under the Help menu in Configuration Wizard 2. For more information, please refer to the Configuration Wizard 2 documentation. The documentation and software are available from the Downloads webpage (www.silabs.com/mcudownloads). 4 Rev. 0.2 C8051F55x/56x/57x 5. Target Board The C8051F560 Development Kit includes a target board with a C8051F568 (Side A) and C8051F550 (Side B) device pre-installed for evaluation and preliminary software development. Numerous input/output (I/O) connections are provided to facilitate prototyping using the target board. Refer to Figure 4 for the locations of the various I/O connectors. Figure 5 on page 7 shows the factory default shorting block positions. A summary of the signal names and headers is provided in Table 12 on page 15. J7 J21 P4 P5 TB1 TB2 Header to choose between +5V from Debug Adapter (P2) or +5V from on-board regulator (U6) Connect V_HIGH node from TB1 LIN header to +5V regulator input for board power Power connector (accepts input from 7 to 15 VDC unregulated power adapter) USB connector (connects to PC for serial communication) Shared LIN Connector for Side A and B MCUs for external nodes Shared CAN Connector for Side A and B MCUs for external nodes J0-J3 J4 J9, J10 J14 J17 J18 J19 J20 J22 J23 J24 P1 P2 TB3 Side A: Port 0 through Port 3 headers Side A: Connects +5V net or +3.3V net to VIO of the MCU Side A: External crystal enable connectors Side A: CAN Transceiver (U3) power connector Side A: Connects MCU to three separate transceivers (UART(U5), CAN(U3), and LIN(T1)) Side A: Connects VIO to VIO_A_SRC which powers the R27 potentiometer, the RST_A pin pull-up, and P1.4_A Switch pull-up. Side A: Connects P1.3_A LED and P1.4_A Switch to MCU port pins Side A: Connects R27 potentiometer to port pin 1.2 Side A: Connects decoupling capacitors C28 and C29 for MCU VREF (P0.0) Side A: Connects VIO_A power to External Memory Interface Latch (U8) Side A: Connects +5V net to VIO and VREGIN of the MCU Side A: 96-pin female connector Side A: DEBUG connector for Debug Adapter interface Side A: Power supply terminal block J5 J6 J8 J11 J12 J13 J15 J16 P3 Side B: Connects decoupling capacitors C42 and C43 for MCU VREF (P0.0) Side B: Connects +5V net to VIO and VREGIN of the MCU Side B: CAN Transceiver (U4) power connector Side B: Port 0 header Side B: Connects MCU to two separate transceivers (CAN (U4) and LIN (T2)) Side B: Port 1 header Side B: Connects P1.3_B LED and P1.4_B Switch to MCU port pins Side B: Port 2 header Side B: DEBUG connector for Debug Adapter interface Rev. 0.2 5 C8051F55x/56x/57x SIDE "B" DS4 1 J4 2 J20 SIDE "A" J22 J23 J3 P1.3_A P1.4_A 1 J2 Port_1 "A" CAN_H U2 1 J10 J7 RESET_A 2 2 1 J13 2 J9 PWR LED J21 DS3 P1.4_B 1 SILICON LABS DEBUG_A P4 TB3 DEBUG_B P3 Rev. 0.2 J15 Port_2 "B" P1.3_B DS1 Figure 4. C8051F560 Target Board with Pin Numbers 6 J11 Port_1 "B" F550 www.silabs.com J1 P2 1 C8051F560-TB 1 1 1 2 1 2 LIN GND J6 J5 J17 J18 2 2 J12 J24 2 J19 Port_2 "A" J8 C8051 F568 DS2 Port_0 "B" 1 2 U1 1 GND J14 LIN Port_3 "A" +LIN_V CP 2102 COMM J0 LIN_OUT 1 TB2 R27 CAN 2 TB1 P5 CAN_L Port_0 "A" CAN P1 2 RESET_B 1 J16 C8051F55x/56x/57x 5.1. Target Board Shorting Blocks: Factory Defaults The C8051F560 Target Board comes from the factory with pre-installed shorting blocks on many headers. Figure 5 shows the positions of the factory default shorting blocks. SIDE "B" P1 SIDE "A" J4 P1.3_A J22 J17 J1 P2 LIN F550 J13 C8051F560-TB J7 J9 J21 PWR P1.4_B DS3 SILICON LABS www.silabs.com DEBUG_A Port_1 "B" U2 J19 RESET_A GND J6 J24 J10 Port_1 "A" J12 J5 J18 J2 CAN_L J8 C8051 F568 DS2 Port_2 "A" Port_0 "B" J11 J23 P1.4_A CAN_H J14 U1 J3 GND +LIN_V J20 DS4 LIN Port_3 "A" LIN_OUT CP 2102 COMM J0 TB2 TB1 R27 CAN P5 CAN Port_0 "A" P4 J15 Port_2 "B" P1.3_B DS1 TB3 DEBUG_B J16 RESET_B P3 Figure 5. C8051F560 Target Board Shorting Blocks: Factory Defaults Rev. 0.2 7 C8051F55x/56x/57x 5.2. Target Board Power Options and Current Measurement (J4, J6, J7, J24, P4, TB1) The MCUs on the C8051F560 Target Board are powered from a +5 V net. The +5 V net is connected to the headers J4 and J24 (Side A) and J6 (Side B). Shorting blocks can be put on each header to connect the 5V net to the VREGIN and VIO pins on the two MCUs. With the shorting blocks removed, a source meter can be used across the headers to measure the current consumption of the MCU. The +5 V net on the target board has three possible sources: 1. 12V dc power using the ac to dc power adapter (P4) 2. 5V dc USB VBUS power from PC via the USB Debug Adapter (DEBUG_A) 3. 12V dc power from the LIN external header (TB1) 5.2.1. Using the AC to DC Power Adapter as the Target Board Power Source (P4, J7) The default configuration of the target board uses the ac to dc power adapter as the source. The 12 V from the adapter is regulated to +5 V using an LDO regulator (U6). The output of the regulator is connected to the +5 V net of the target board through the J7 header. A shorting block should be installed on pins J7[2-3] for this purpose. The +5V net powers the MCUs directly. 5.2.2. Using the USB Debug Adapter as the Target Board Power Source (J7) The target board can use +5 V provided by the USB Debug Adapter. To enable this source, a shorting block should be installed on pins J7[1-2]. With this shorting block, the output of the LDO regulator (U6) is disconnected from the +5 V net of the target board, and the SER_PWR node is connected to +5 V. Note: The USB Debug Adapter does not provide the necessary peak power for the CAN transceivers to operate. One of the 12 V dc sources is recommended for CAN transceiver operation. 5.2.3. Using an External +12V LIN Source as the Target Board Power Source (J7, TB1) The two 12V power sources (LIN and ac to dc power adapter) are ORed together using reverse-biased diodes (Z1 and Z2) and connected to the input of the LDO regulator (U6). The output of the regulator is connected to the +5 V net of the target board through the J7 header. A shorting block should be installed on pins J7[2-3] for this purpose. The +5V net powers the MCUs directly. 5.3. System Clock Sources (J9, J10) 5.3.1. Internal Oscillators The C8051F568 and C8051F550 devices installed on the target board feature a factory-calibrated, programmable high-frequency internal oscillator (24 MHz base frequency, 0.5%), which is enabled as the system clock source on reset. After reset, the internal oscillator operates at a frequency of 187.5 kHz by default but may be configured by software to operate at other frequencies. The on-chip crystal is accurate for CAN and LIN master communications and in many applications an external oscillator is not required. However, if you wish to operate the C8051F568 device (Side A) at a frequency not available with the internal oscillator, an external crystal may be used. Refer to the C8051F55x/56x/57x data sheet for more information on configuring the system clock source. 5.3.2. External Oscillator Options The target board is designed to facilitate the installation of an external crystal. Remove shorting blocks at headers J9 and J10 and install the crystal at the pads marked Y1. Install a 10 M resistor at R2 and install capacitors at C6 and C7 using values appropriate for the crystal you select. If you wish to operate the external oscillator in capacitor or RC mode, options to install a capacitor or an RC network are also available on the target board. R2, R3, C6, and C7 are located on the back side of the board, near the Side A MCU. Populate C6 for capacitor mode, and populate R3 and C6 for RC mode. Refer to the C8051F55x/56x/57x data sheet for more information on the use of external oscillators. 8 Rev. 0.2 C8051F55x/56x/57x 5.4. Switches and LEDs (J15, J19) Two push-button switches are provided on the target board for each MCU. Switch RESET_A is connected to the RST pin of the C8051F568. Switch RESET_B is connected to the RST pin of the C8051F550. Pressing RESET_A puts the C8051F568 device into its hardware-reset state, and similarly for RESET_B and the C8051F550 MCU. Switches P1.4_A and P1.4_B are connected to the MCU's general purpose I/O (GPIO) pins through headers. Pressing either one of these switches generates a logic low signal on the port pin. Remove the shorting block from the header to disconnect these switches from the port pins. See Table 1 for the port pins and headers corresponding to each switch. Four LEDs are provided on the target board to serve as indicators. The red LED labeled PWR LED indicates presence of power to the target board. The second red LED labeled COMM indicates if the CP2102 USB-to-UART bridge is recognized by the PC. The green LED on Side A is labeled with a port pin name and is connected to a C8051F568 GPIO pin through a header. Remove the shorting block from the header to disconnect the LED from the port pin. Similarly, a second green LED on Side B is connected to the C8051F550 through another header. See Table 1 for the port pins and headers corresponding to each LED. Table 1. Target Board I/O Descriptions Description I/O Header(s) RESET_A RESET_B P1.4_A Switch P1.4_B Switch P1.3_A LED P1.3_B LED Red LED (PWR) Red LED (COMM) Reset (Side A) Reset (Side B) P1.4 (Side A) P1.4 (Side B) P1.3 (Side A) P1.3 (Side B) Power COMM Active none none J19[1-2] J15[1-2] J19[3-4] J15[3-4] none none 5.5. Target Board Debug Interfaces (P2 and P3) The debug connectors P2 (DEBUG_A) and P3 (DEBUG_B) provide access to the debug (C2) pins of the C8051F568 and C8051F550. The debug connectors are used to connect the Serial Adapter or the USB Debug Adapter to the target board for in-circuit debugging and Flash programming. Table 2 shows the DEBUG pin definitions. Table 2. DEBUG Connector Pin Descriptions Side A - C8051F568 Side B - C8051F550 Pin # Description Pin # Description 1 Not Connected 1 Not Connected 2, 3, 9 GND (Ground) 2, 3, 9 GND (Ground) 4 P4.0_C2D_A 4 P2.1_C2D_B 5 RST_A (Reset) 5 RST_B (Reset) 6 P4.0_A 6 P2.1_B 7 RST/C2CK_A 7 RST/C2CK_B 8 Not Connected 8 Not Connected 10 USB Power (+5VDC from P2) 10 Not Connected Rev. 0.2 9 C8051F55x/56x/57x 5.6. Serial Interface (P5, J17) A USB-to-UART bridge circuit (U5) and USB connector (P5) are provided on the target board to facilitate serial connections to UART0 of the C8051F568 (Side A). The Silicon Labs CP2102 USB-to-UART bridge provides data connectivity between the C8051F568 and the PC via a USB port. The TX and RX signals of UART0 may be connected to the CP2102 by installing shorting blocks on header J17. The shorting block positions for connecting each of these signals to the CP2102 are listed in Table 3. To use this interface, the USB-to-UART device drivers should be installed as described in Section C8051F560. Table 3. Serial Interface Header (J17) Description Header Pins UART0 Pin Description J17[3-4] J17[1-2] UART_TX (P0.4_A) UART_RX (P0.5_A) 5.7. CAN Interface and Network (J8, J12, J14, J17, TB2) Both MCUs on the target board are connected to CAN transceivers (U3, U4) through headers. The port pins assigned to the CAN peripheral on each MCU are P0.6 (CAN_TX) and P0.7 (CAN_RX). The C8051F568 (Side A) is connected to U3 through the J17 header and the C8051F550 (Side B) is connected to U4 through the J12 header. The two CAN transceivers are connected to each other and form a CAN network. Other external devices can be connected to the CAN network through the TB2 interface. The shorting block positions for connecting the MCUs to the CAN transceivers are listed in Table 4. The pin connections for the external CAN devices are listed in Table 5. The CAN transceivers are powered by the +5VREG node and connected through J8 and J14 headers. Table 4. CAN Interface Headers (J17 and J12) Description Header Pins CAN0 Pin Description J17[5-6] J17[7-8] J12[7-8] J12[5-6] CAN_TX (P0.6_A) CAN_RX (P0.7_A) CAN_TX (P0.6_B) CAN_RX (P0.7_B) Table 5. TB2 External CAN Interface Header Description 10 Pin # Pin Description 1 2 3 GND CAN_L CAN_H Rev. 0.2 C8051F55x/56x/57x 5.8. LIN Interface and Network (J12, J17, J21, TB1) Both MCUs on the target board are connected to LIN transceivers through headers. These headers assume that the MCU's crossbars are configured to put the LIN TX and RX pins on port pins P1.0 and P1.1 respectively. See the C8051F55x/56x/57x data sheet for crossbar configuration. The C8051F568 (Side A) is connected to the T1 transceiver through the J17 header and the C8051F550 (Side B) is connected to the T2 transceiver through the J12 header. The two LIN transceivers are connected to each other and form a LIN network. Other external devices can be connected to the LIN network through the TB1 interface. The TB1 interface also provides the option for connecting an external power source so that all LIN transceivers can use the same source voltage. This source voltage can also be used to power the target board. If an external voltage source is not provided, the LIN transceivers use the 12V provided through the P4 power adapter connector. See Section 5.2. for more power option details. The shorting block positions for connecting the MCUs to the LIN transceivers are listed in Table 6. The pin connections for the external LIN devices are listed in Table 7. Table 6. LIN Interface Headers (J12 and J17) Description Header Pins LIN0 Pin Description J17[9-10] J17[11-12] J12[3-4] J12[1-2] LIN_TX (P1.0_A) LIN_RX (P1.1_A) LIN_TX (P1.0_B) LIN_RX (P1.1_B) Table 7. TB1 External LIN Interface Header Description Pin # Pin Description 1 2 3 GND LIN_OUT +LIN_V Header J21 connects the P4 power-adapter supply to the V_HIGH node, which is used as the power source for the LIN transceivers (T1, T2). The shorting block on header J21 can be removed to force the LIN transceivers to use the voltage supply externally supplied on the +LIN_V pin on the TB1 header. Rev. 0.2 11 C8051F55x/56x/57x 5.9. Port I/O Connectors (J0-J3 and J11, J13, J16) Each of the parallel ports of the C8051F568 (Side A) and C8051F550 (Side B) has its own 10-pin header connector. Each connector provides a pin for the corresponding port pins 0-7, +5 V VIO, and digital ground. The same pin-out is used for all of the port connectors. Table 8. Port I/O Connector Pin Description (J0-J3, J11, J13) Pin # Pin Description 1 2 3 4 5 6 7 8 9 10 Pn.0 Pn.1 Pn.2 Pn.3 Pn.4 Pn.5 Pn.6 Pn.7 +5V (VIO) GND (Ground) Port 2 on the C8051F550 (Side B) MCU has only two pins and has a reduced header. Table 9. Port I/O Connector Pin Description (J16) Pin # Pin Description 1 2 3 4 Pn.0 Pn.1 +5V (VIO) GND (Ground) 5.10. Voltage Reference (VREF) Connectors (J5 and J22) The VREF connectors can be used to connect the VREF pin from the MCU (P0.0) to external 0.1 F and 4.7 F decoupling capacitors. The C8051F568 (Side A) device is connected to the capacitors through the J22 header and the C8051F550 (Side B) device connects to its own set of capacitors through J5. 12 Rev. 0.2 C8051F55x/56x/57x 5.11. Expansion Connector (P1) The 96-pin expansion I/O connector P1 is used to connect daughter boards to the main target board. P1 provides access to many C8051F568 signal pins. Pins for VREGIN, VDD, VIO, and 3.3V are also available. See Table 10 for a complete list of pins available at P1. The P1 socket connector is manufactured by Hirose Electronic Co. Ltd, part number PCN13-96S-2.54DS, Digi-Key part number H7096-ND. The corresponding plug connector is also manufactured by Hirose Electronic Co. Ltd, part number PCN10-96P-2.54DS, Digi-Key part number H5096-ND. Pin # Description A-1 A-2 A-3 A-4 A-5 A-6 A-7 A-8 A-9 A-10 A-11 A-12 A-13 A-14 A-15 A-16 A-17 A-18 A-19 A-20 A-21 A-22 A-23 A-24 A-25 +3.3V N/C N/C N/C N/C N/C N/C N/C N/C N/C P0.5_A P_0.2_A P3.7_A P3.4_A P3.1_A P3.6_A_L P3.3_A_L P3.0_A_L P2.5_A P2.2_A P1.7_A P1.2_A P1.1_A P4.0_C2D_A A-26 A-27 A-28 A-29 A-30 A-31 A-32 RST_A GND N/C N/C VIO_A N/C N/C N/C Table 10. P1 Pin Listing Pin # Description Pin # Description B-1 B-2 B-3 B-4 B-5 B-6 B-7 B-8 B-9 B-10 B-11 B-12 B-13 B-14 B-15 B-16 B-17 B-18 B-19 B-20 B-21 B-22 B-23 B-24 B-25 GND N/C N/C N/C N/C N/C N/C N/C N/C P0.7_A P0.4_A P0.1_A P3.6_A P3.3_A P3.0_A P3.5_A_L P3.2_A_L P2.7_A P2.4_A P2.1_A P1.6_A P1.3_A P1.0_A N/C GND C-1 C-2 C-3 C-4 C-5 C-6 C-7 C-8 C-9 C-10 C-11 C-12 C-13 C-14 C-15 C-16 C-17 C-18 C-19 C-20 C-21 C-22 C-23 C-24 C-25 N/C N/C N/C N/C N/C N/C N/C N/C N/C P0.6_A P_0.3_A P0.0_A P3.5_A P3.2_A P3.7_A_L P3.4_A_L P3.1_A_L P2.6_A P2.3_A P2.0_A P1.4_A P1.5_A N/C N/C N/C B-26 B-27 B-28 B-29 B-30 B-31 B-32 N/C N/C N/C VDD_A N/C N/C AGND C-26 C-27 C-28 C-29 C-30 C-31 C-32 N/C N/C N/C VREGIN_A N/C N/C N/C The Silicon Labs add-on boards designed to interface to the 96-pin interface are primarily designed to operate at 3.3 V and to use a non-multiplexed external memory interface. When interfacing to a +3.3 V add-on board, it is recommended to put the shorting block on J4[2-3] to connect VIO of the C8051F568 to +3.3 V instead of the default +5 V. The C8051F560 target board also includes an 8-bit latch (U8) for use with the multiplexed mode of the Rev. 0.2 13 C8051F55x/56x/57x external memory interface. The output pins of the latch are connected to the 96-pin header and include an _L suffix in the pin name. 5.12. Potentiometer (J20) The C8051F568 (Side A) device has the option to connect port pin P1.2 to a 10K linear potentiometer (R27). The potentiometer is connected through the J20 header. The potentiometer can be used for testing the analog-to-digital (ADC) converter of the MCU. 5.13. Power Supply I/O (Side A) (TB3) All of the C8051F568 target device's supply pins are connected to the TB3 terminal block. Refer to Table 11 for the TB3 terminal block connections. Table 11. TB3 Terminal Block Pin Descriptions Pin # Description 1 2 3 4 5 6 VIO_A VREGIN_A VDD_A VDDA_A GNDA_A GND 5.14. Alternate Power Supply Headers (J18, J21) The C8051F560 Target Board includes two headers that allow for alternate power sources and power measurement. Header J18 connects the VIO voltage supplied to the Side A MCU to other peripherals on the board, such as the P1.4_A push-button switch pull-up, and the R27 potentiometer source. To enable current measurement, the shorting block on J18 can be removed so that the VIO_A node only powers the VIO pin on the MCU. Another voltage source will need to be applied to the VIO_SRC node to power the other peripherals. 5.15. C2 Pin Sharing On the C8051F568 (Side A) and the C8051F550 (Side B), the debug pins C2CK and C2D are shared with the pins RST and P4.0/P2.1 respectively. The target board includes the resistors necessary to enable pin sharing which allow the pin-shared pins to be used normally while simultaneously debugging the device. See Application Note "AN124: Pin Sharing Techniques for the C2 Interface" at www.silabs.com for more information regarding pin sharing. 14 Rev. 0.2 C8051F55x/56x/57x 5.16. Target Board Pin Assignment Summary Some GPIO pins of the C8051F568 MCU can have an alternate fixed function. For example, pin 38 on the C8051F568 MCU is designated P0.4, and can be used as a GPIO pin. Also, if the UART0 peripheral on the MCU is enabled using the crossbar registers, the TX signal is routed to this pin. This is shown in the "Alternate Fixed Function" column. The "Target Board Function" column shows that this pin is used as TX on the C8051F560 Target Board. The "Relevant Headers" column shows that this signal is routed to pin 3 of the J17 header and pin 5 of the J1 header. More details can be found in the C8051F55x/56x/57x data sheet. Some of the GPIO pins of the C8051F568 have been used for various functions on the target board. All pins of the Side A MCU also connect to the 96-pin (P1) expansion connector which is not explicitly listed below. Table 12 summarizes the C8051F568 MCU pin assignments on the target board, and also shows the various headers associated with each signal. Table 12. C8051F560 Target Board Pin Assignments and Headers MCU Pin Name Pin# Primary Function Alternate Fixed Function Target Board Function Relevant Headers P0.0 8 P0.0 VREF VREF J0[1], J22[1] P0.1 1 P0.1 CNVSTR CNVSTR J0[2] P0.2 40 P0.2 XTAL1 XTAL1 J0[3]*, J9[2] P0.3 39 P0.3 XTAL2 XTAL2 J0[4]*, J10[2] P0.4 38 P0.4 UART_TX TX_MCU J0[5], J17[3] P0.5 37 P0.5 UART_RX RX_MCU J0[6], J17[1] P0.6 36 P0.6 CAN_TX CAN_TX J0[7], J17[5] P0.7 35 P0.7 CAN_RX CAN_RX J0[8], J17[7] P1.0 34 P1.0 LIN_TX J1[1], J17[9] P1.1 33 P1.1 LIN_RX J1[2], J17[11] P1.2 32 P1.2 POTENTIOMETER J1[3], J20[1] P1.3 31 P1.3 LED J1[4], J19[4] P1.4 30 P1.4 SWITCH J1[5], J19[2] P1.5 29 P1.5 GPIO J1[6] P1.6 28 P1.6 GPIO J1[7] P1.7 27 P1.7 GPIO J18] P2.0 26 P2.0 GPIO J2[1] P2.1 25 P2.1 GPIO J2[2] P2.2 24 P2.2 GPIO J2[3] P2.3 23 P2.3 GPIO J2[4] P2.4 22 P2.4 GPIO J2[5] P2.5 21 P2.5 GPIO J2[6] P2.6 20 P2.6 GPIO J2[7] P2.7 19 P2.7 GPIO J2[8] P3.0 18 P3.0 GPIO J3[1] ALE (U8) Rev. 0.2 15 C8051F55x/56x/57x Table 12. C8051F560 Target Board Pin Assignments and Headers (Continued) MCU Pin Name Pin# Primary Function P3.1 17 P3.2 Alternate Fixed Function Target Board Function Relevant Headers P3.1 GPIO J3[2] 16 P3.2 GPIO J3[3] P3.3 15 P3.3 GPIO J3[4] P3.4 14 P3.4 GPIO J3[5] P3.5 13 P3.5 GPIO J3[6] P3.6 12 P3.6 GPIO J3[7] P3.7 11 P3.7 GPIO J3[8] P4.0_C2D 9 C2D P4.0 GPIO P2[4], P2[6]* RST/C2CK 10 RST C2CK RST/C2CK P2[7], P2[5]* VIO 2 VIO VIO J4[2], J18[1], TB3[1] J0-J3[9]*, J23 VREGIN 3 VREGIN VREGIN J24[2], TB3[2] VDD 4 VDD VDD TB3[3] VDDA 5 VDDA VDDA TB3[4] GND 6 GND GND J0-J3[10], TB3[6] GNDA 7 GNDA GNDA TB3[5] *Note: Headers denoted by this symbol are not directly connected to the MCU pin; the connection might be via one or more headers and/or pin-sharing resistor(s). See board schematic for details. 16 Rev. 0.2 Figure 6. C8051F560 Target Board Schematic (Page 1 of 4) C8051F55x/56x/57x 6. Schematics Rev. 0.2 17 Figure 7. C8051F560 Target Board Schematic (Page 2 of 4) C8051F55x/56x/57x 18 Rev. 0.2 Figure 8. C8051F560 Target Board Schematic (Page 3 of 4) C8051F55x/56x/57x Rev. 0.2 19 Figure 9. C8051F560 Target Board Schematic (Page 4 of 4) C8051F55x/56x/57x 20 Rev. 0.2 C8051F55x/56x/57x DOCUMENT CHANGE LIST Revision 0.1 to Revision 0.2 Updated 4. "Software Setup" on page 2. Rev. 0.2 21 Simplicity Studio One-click access to MCU and wireless tools, documentation, software, source code libraries & more. Available for Windows, Mac and Linux! IoT Portfolio www.silabs.com/IoT SW/HW Quality Support and Community www.silabs.com/simplicity www.silabs.com/quality community.silabs.com Disclaimer Silicon Laboratories intends to provide customers with the latest, accurate, and in-depth documentation of all peripherals and modules available for system and software implementers using or intending to use the Silicon Laboratories products. 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