Get Started with the LPCXpresso804
このドキュメントの内容
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Plug It In
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Get Software
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Import, Build, Run
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お客様の OM40001
Plug It In
Let's take your LPCXpresso804 board for a test drive You have the choice of watching the sequence in a short video or following the detailed actions list below.
Get Started with LPCXpresso804 Development Platform - Demo
1.1 Install Drivers
On windows 7 or 8 platforms, before using your board it is recommended that you install the VCOM device driver. Start by downloading the firmware and driver package and from here
1.2 Serial Terminal
The out-of-box demo and some Code Bundle UART examples set up for IAR and Keil tools use the MCU UART for print output, and this is also an option for the MCUXpresso IDE. If you are not sure how to use a terminal application try one of these tutorials:
1.3 Plug in the Board
The LPCXpresso804 board is shipped with the Capacitive Touch Shield installed for packaging purposes. The Shield should be removed before powering the board up in order to gain access to the potentiometer (see below). Note that the LPC804 Code Bundle includes example programs for use of this Shield.
The LPCXpresso804 board is pre-programmed with a diagnostic demo program, which tests various features of the board. This program utilizes the UART LPC804 output, which is connected to the debug probe, which acts a serial to USB bridge to a host computer (as well as providing the CMSIS-DAP debug interface.) To ensure a correct operation, be sure to follow step 1.1 to install the VCOM serial port driver before powering the board when using Windows 7 or 8 host computer.
Connect a micro USB cable from connector CN2 to a host computer or power supply to power up the board and run the demo program. Open a terminal emulator program (such as Teraterm or PuTTY), and look for a port with a name of the form “NXP LPC11Uxx VCOM ...”, and connect to it. Set the serial port for 9600 baud, 8 bits, no parity.
- The Blue user LED will flash 3 times, then the green LED will flash 3 times, and the terminal will display “HelloWorld”, followed by “Press key to start LED test ...”
- Press the ISP button (S2). The green and blue user LEDs will flash, then each LED will be lit in turn twice before all three blink 3 times. The terminal will show “DONE”.
- The terminal will show “Press key to start SpiFlash test”. Press the ISP button. The LEDs will blink as the test is run, and the SPI flash device ID and name will be shown on the terminal.
- The terminal will show “Press key to start I2cTemperature test ...”. Press the ISP button to run this test, which checks communication with the LM75 temperature sensor.
- The terminal will show “Press key to start ADC Potentiometer test ...”. Press the ISP button to run this test. The test checks the LPC804 ADC and potentiometer (VR1), looking for the ADC reading to change at least once as it takes 6 samples over several seconds. You can use the supplied screwdriver to adjust VR1 so the test passes.
Tera Term Tutorial
Tera Term is a very popular open source terminal emulation application. This program can be used to display information sent from your NXP development platform's virtual serial port.
- Download Tera Term from SourceForge. After the download, run the installer and then return to this webpage to continue.
- Launch Tera Term. The first time it launches, it will show you the following dialog. Select the serial option. Assuming your board is plugged in, there should be a COM port automatically populated in the list.
- Configure the serial port settings (using the COM port number identified earlier) to 115200 baud rate, 8 data bits, no parity and 1 stop bit. To do this, go to Setup -> Serial Port and change the settings.
- Verify that the connection is open. If connected, Tera Term will show something like below in it's title bar.
- You're ready to go
PuTTY Tutorial
PuTTY is a popular terminal emulation application. This program can be used to display information sent from your NXP development platform's virtual serial port.
- Download PuTTY using the button below. After the download, run the installer and then return to this webpage to continue.
- Launch PuTTY by either double clicking on the *.exe file you downloaded or from the Start menu, depending on the type of download you selected.
- Configure In the window that launches, select the Serial radio button and enter the COM port number that you determined earlier. Also enter the baud rate, in this case 115200.
- Click Open to open the serial connection. Assuming the board is connected and you entered the correct COM port, the terminal window will open. If the configuration is not correct, PuTTY will alert you.
- You're ready to go
Get Software
2.1 Jump Start Your Design with the Code Bundles
LPC8xx Family Code Bundles are easy to understand drivers and examples, with full source code provided.
Get Code for LPC81x
Get Code for LPC82x
Get Code for LPC83x
Get Code for LPC84X
2.2 Install your Toolchain
NXP offers a free, GNU/Eclipse based toolchain called MCUXpresso IDE. Note that MCUXpresso IDE 10.1.1 requires a patch to support LPC804; this patch is available at the IDE download page.
Want to use a different toolchain?
No problem Code Bundles are also available for IAR and Keil
Import, Build, Run
3.1 Build, Run
MCUXpresso IDE version 10.1 or later should be used with LPC804. A patch (available at the MCUXpresso IDE page) is available, and once installed, this will provide the IDE with built-in knowledge of the LPC804 part family, so does not require any SDK installation steps. Note that version 10.1 may not report the LPC804 memory size correctly and does not include a picture of the LPCXpresso804 board. From version 10.2 (due for release in Q2 2018), the IDE will not require a patch and will include the board information.
Follow the steps below to build and run a simple example from the LPC804 Code Bundle provided by NXP. These can also be downloaded from nxp.com:
Get Code for LPC81x
Get Code for LPC82x
Get Code for LPC83x
Get Code for LPC84X
1. Open a new workspace in the IDE.
2. In the Quickstart panel of the IDE, click in “Import project(s) from the file system”.
3. In the “Import project(s) from file system...” dialog box that opens, click “Browse...” in the Project Archive (from zip) section, and select the LPC804 Code Bundle zip file from the Code Bundles directory in the MCUXpresso IDE installation (or select a version downloaded from nxp.com, as described in Step 1 above.) Click “Next >” on the “Import project(s) from file system...” dialog to continue.
4. You will see several projects listed in the Code Bundle; click “Finish” to import them all.
5. The dialog box will close, and you will see the imported projects in the Project tab at the upper left window of the IDE. Click on Example_Multi_Timer_Blinky to select it, then select Build from the Quickstart panel. You will see the build processing in the Console window to the right of the Quickstart panel. The projects are set up to include dependency checking, so the build process will automatically build the utility and peripheral libraries as well as the example program.
6. Ensuring the LPCXpresso804 is connected to the host computer, click Debug in the Quickstart panel. The IDE will search for available debug probes. Select the debug probe that appears for your board, then click OK. Note that the IDE will remember your selection for the next time you debug this project, so will not prompt for this again, unless it cannot find the board.
7. The code will execute to main. Press F8 to resume and run the program. You will now see the User LEDs light, each color in turn.
3.2 Building and Debugging with MCUXpresso IDE
The video below explains how to load and run a Code Bundle program using the MCUXpresso IDE. The video uses the LPCXpresso845 board; the steps are the same for LPCXpresso804, but be sure to use the Code Bundle for LPC804, not the one for LPC845.
The OM40001 board set includes PLU and Capacitive Touch shield boards, that mount on the LPCXpresso804 board. The Code Bundle for LPC804 includes examples of how to use these. Refer to the OM40001 User Manual for more information on these shield boards.
Demo not working?
Did your board come in a box that looks like this?
No problem Your board simply came in the old packaging and has a different out-of-box demo loaded into the flash memory.
You should be seeing the RGB LED toggling between each of the three colors; red, blue and green. It's OK to move onto the next step when you're ready.
Still not working?
Try proceeding to the next steps to get other example applications running on your board. If you still have problems, try contacting us through the NXP Community.
Running a demo using IAR
1. Build an Example Application
The following steps will guide you through opening the led_output application. These steps may change slightly for other example applications as some of these applications may have additional layers of folders in their path.
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If not already done, open the desired example application workspace. Most example application workspace files can be located using the following path:
/boards/ / / /iar Using the hello_world demo as an example, the path is:
/boards/lpcxpresso54608/driver_examples/gpio/led_output/iar -
Select the desired build target from the drop-down. For this example, select the “hello_world – Debug” target.
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To build the application, click the “Make” button, highlighted in red below.
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The build will complete without errors.:
2. Run an Example Application
The LPCXpresso845-MAX board comes loaded with the CMSIS-DAP debug interface from the factory. Connect the development platform to your PC via USB cable to J8 “Debug Link”.
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Click the "Download and Debug" button to download the application to the target.
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The application is then downloaded to the target and automatically runs to the main() function.
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Run the code by clicking the "Go" button to start the application.
Running a demo using Keil® MDK/µVision®
1. Install CMSIS device pack
After the MDK tools are installed, Cortex® Microcontroller Software Interface Standard (CMSIS) device packs must be installed to fully support the device from a debug perspective. These packs include things such as memory map information, register definitions and flash programming algorithms. Follow these steps to install the appropriate CMSIS pack.
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Open the MDK IDE, which is called µVision. In the IDE, select the "Pack Installer" icon.
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2. In the Pack Installer window, navigate to the section with the LPC packs (they are in alphabetical order). The Kinetis packs start with "Keil::LPC" and are followed by the MCU family name, for example "Keil::LPC54000". Because this example uses the LPCXpresso845-MAX platform, the LPC54000 family pack is selected. Click on the "Install" button next to the pack. This process requires an internet connection to successfully complete.
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After the installation finishes, close the Pack Installer window and return to the µVision IDE.
2. Build the Example Application
The following steps will guide you through opening the gpio_led_output application. These steps may change slightly for other example applications as some of these applications may have additional layers of folders in their path.
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If not already done, open the desired demo application workspace in:
/boards/ / / /mdk The workspace file is named
.uvmpw, so for this specific example, the actual path is: /boards/lpcxpresso54608/driver_examples/gpio/led_output/mdk/gpio_led_output.uvmpw -
To build the demo project, select the "Rebuild" button, highlighted in red.
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The build will complete without errors.
3. Run an Example Application
The LPCXpresso845-MAX board comes loaded with CMSIS-DAP debug interface from the factory.
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After the application is properly built, click the "Download" button to
download the application to the target.
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After clicking the "Download" button, the application downloads to the
target and should be running. To debug the application, click the
"Start/Stop Debug Session" button,
highlighted in red.
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Run the code by clicking the "Run" button to start the application.
Running a demo using Kinetis Design Studio IDE
1. Install KDS Updates
Before using KDS IDE with KSDK, it is recommended that you make sure that your tools are up-to-date. The steps discussed below are shown using the Windows version of KDS, but are identical for Mac and Linux users.
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Select "Help" -> "Check for Updates".
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Install all updates from Freescale/NXP – these are denoted by “com.NXP.xxx” or “com.nxp.xxx”. There may also be updates for things such as toolchain or debug interfaces. While these additional updates are typically OK to install, sometimes they may cause issues since they aren’t released as part of the KDS toolchain.
2. Build an Example Application
The following steps will guide you through opening the hello_world application. These steps may change slightly for other example applications as some of these applications may have additional layers of folders in their path.
NOTE
The steps required for Linux and Mac OS are identical to those for Windows.
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Select File->Import from the KDS IDE menu. In the window that appears, expand the "Project of Projects" folder and select "Existing Project Sets". Then, click the "Next" button.
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Click the "Browse" button next to the "Import from file:" option.
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Point to the example application project, which can be found using this path:
/boards/ / / /kds For this guide, choose the specific location:
/boards/frdmke15z/demo_apps/hello_world/kds -
After pointing to the correct directory, your "Import Working Sets and Projects" window should look like the figure below. Click the "Finish" button.
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There are two project configurations (build targets) supported for each KSDK project:
- Debug – Compiler optimization is set to low, and debug information is generated for the executable. This target should be selected for development and debug.
- Release – Compiler optimization is set to high, and debug information is not generated. This target should be selected for final application deployment.
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Choose the appropriate build target, "Debug" or "Release", by clicking the downward facing arrow next to the hammer icon, as shown below. For this example, select the "Debug" target.
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The library starts building after the build target is selected. To rebuild the library in the future, click the hammer icon (assuming the same build target is chosen).
3. Run an Example Application
The FRDM-KE15Z board comes loaded with the mbed/CMSIS-DAP debug interface from the factory. If you have changed the debug OpenSDA application on your board, visit http://www.nxp.com/opensda for information on updating or restoring your board to the factory state.
NOTE
Mac users must install the J-Link OpenSDA application in order to use the KDS IDE to download and debug their board.
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Connect the development platform to your PC via USB cable between the "SDAUSB" USB port on the board and the PC USB connector.
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Open the terminal application on the PC (such as PuTTY or TeraTerm) and connect to the debug COM port you determined earlier. Configure the terminal with these settings:
- 15200 baud rate
- No parity
- 8 data bits
- 1 stop bit
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For Linux OS users only, run the following commands in your terminal. These install libudev onto your system, which is required by KDS IDE to launch the debugger.
user@ubuntu:~$ sudo apt-get install libudev-dev libudev1user@ubuntu:~$ sudo ln –s /usr/lib/x86_64-linux-gnu/libudev.so /usr/lib/x86_64-linux-gnu/libudev.so.0 -
Ensure that the debugger configuration is correct for the target you're attempting to connect to. This refers to the OpenSDA interface of your board. If you’re unsure what your board has, please consult Appendix B of the PDF linked in the top right hand corner of this dialog.
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To check the available debugger configurations, click the small downward arrow next to the green "Debug" button and select "Debug Configurations".
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In the Debug Configurations dialog box, select debug configuration that corresponds to the hardware platform you’re using. For Windows or Linux users, select is the mbed/CMSIS-DAP option under OpenOCD For Mac users, select J-Link.
After selecting the debugger interface, click the "Debug" button to launch the debugger.
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The application is downloaded to the target and automatically run to main():
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Start the application by clicking the "Resume" button:
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The hello_world application is now running and a banner is displayed on the terminal. If this is not the case, check your terminal settings and connections.
Running a demo using Atollic
1. Build an Example Application
The following steps will guide you through opening the hello_world application. These steps may change slightly for other example applications as some of these applications may have additional layers of folders in their path.
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Select "File -> Import" from the TrueSTUDIO menu. Expand the "General" folder and select "Existing Projects into Workspace". Then, click the "Next" button.
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Click the "Browse" button next to the "Select root directory:" option.
Point to the example application project, which can be found using this path:
/boards/ / / /atl For this guide, the specific location is:
/boards/frdmke15z/demo_apps/hello_world/atl -
After pointing to the correct directory, your "Import Projects" window should look like this figure. Click the "Finish" button.
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There are two project configurations (build targets) supported for each KSDK project:
- Debug – Compiler optimization is set to low, and debug information is generated for the executable. This target should be selected for development and debug.
- Release – Compiler optimization is set to high, and debug information is not generated. This target should be selected for final application deployment.
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Choose the appropriate build target, "Debug" or "Release", by clicking the "Manage build configurations" icon, as shown below. For this example, select the "Debug" target and click "Set Active". Since the default configuration is to use the Debug target, there should not be a change required.
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Click the "Build" icon to build the application.
2. Run an Example Application
The Atollic tools require a J-Link debug interface. To update the OpenSDA firmware on your board to the latest J-Link app, visit www.nxp.com/opensda.
To install the JLink OpenSDAv2.1 application on the board:
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With the board unpowered, hold down the Reset button on the board and plug in a micro-B USB cable into the “SDA USB” USB port on the board.
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Release the Reset button.
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The board will enumerate as a “BOOTLOADER” driver.
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Drag and drop the JLink OpenSDAv2.1 application .bin file into this drive.
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Do a power cycle, and now the board will be running the JLink OpenSDA application.
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Open the terminal application on the PC (such as PuTTY or TeraTerm) and connect to the debug COM port you determined earlier. Configure the terminal with these settings:
- 15200 baud rate
- No parity
- 8 data bits
- 1 stop bit
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Ensure that the debugger configuration is correct for the target you're attempting to connect to.
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To check the available debugger configurations, click the "Configure
Debug" icon.
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Select the J-Link "Debug" interface and click the "Debug" button.
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To check the available debugger configurations, click the "Configure
Debug" icon.
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The application is downloaded to the target and automatically run to main():
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Run the application by clicking the "Resume" button:
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The hello_world application is now running and a banner is displayed on the terminal.
After the J-Link OpenSDA app is loaded on the board:
Running a demo using Arm
1. Set Up Toolchain
This section contains the steps to install the necessary components required to build and run a KSDK demo application with the Arm GCC toolchain, as supported by the Kinetis SDK. There are many ways to use Arm GCC tools, but this example focuses on a Windows environment. Though not discussed here, GCC tools can also be used with both Linux OS and Mac OSX.
Install GCC Arm Embedded Toolchain
Download and run the installer from launchpad.net/gcc-arm-embedded. This is the actual toolchain (i.e., compiler, linker, etc.). The GCC toolchain should correspond to the latest supported version, as described in the Kinetis SDK Release Notes.
Install MinGW
The Minimalist GNU for Windows (MinGW) development tools provide a set of tools that are not dependent on third party C-Runtime DLLs (such as Cygwin). The build environment used by the KSDK does not utilize the MinGW build tools, but does leverage the base install of both MinGW and MSYS. MSYS provides a basic shell with a Unix-like interface and tools.
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Download the latest MinGW mingw-get-setup installer from sourceforge.net/projects/mingw/files/Installer/.
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Run the installer. The recommended installation path is C:\MinGW, however, you may install to any location.
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Ensure that the "mingw32-base" and "msys-base" are selected under Basic Setup.
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Click "Apply Changes" in the "Installation" menu and follow the remaining instructions to complete the installation.
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Add the appropriate item to the Windows operating system Path environment variable. It can be found under Control Panel -> System and Security -> System -> Advanced System Settings in the "Environment Variables..." section. The path is:
\bin Assuming the default installation path, C:\MinGW, an example is shown below. If the path is not set correctly, the toolchain does not work.
NOTE
If you have "C:\MinGW\msys\x.x\bin" in your PATH variable (as required by KSDK 1.0.0), remove it to ensure that the new GCC build system works correctly.
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Download CMake 3.0.x from www.cmake.org/cmake/resources/software.html.
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Install CMake, ensuring that the option "Add CMake to system PATH" is selected when installing. It's up to the user to select whether it's installed into the PATH for all users or just the current user. In this example, the assumption is that it's installed for all users.
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Follow the remaining instructions of the installer.
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You may need to reboot your system for the PATH changes to take effect.
NOTE
The installation path cannot contain any spaces.
Add a New Environment Variable for ArmGCC_DIR
Create a new system environment variable and name it ArmGCC_DIR. The value of this variable should point to the Arm GCC Embedded tool chain installation path, which, for this example, is:
C:\Program Files (x86)\GNU Tools Arm Embedded\4.9 2015q3
Reference the installation folder of the GNU Arm GCC Embedded tools for the exact path name of your installation.
Install CMake
2. Build an Example Application
To build an example application, follow these steps.
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1. If not already running, open a GCC Arm Embedded tool chain command window. To launch the window, from the Windows operating system Start menu, go to “Programs -> GNU Tools Arm Embedded
” and select “GCC Command Prompt”. 
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Change the directory to the example application project directory, which has a path like this:
/boards/ / / /armgcc For this guide, the exact path is:
/boards/frdmke15z/demo_apps/hello_world/armgcc -
Type “build_debug.bat” on the command line or double click on the "build_debug.bat" file in Windows operating system Explorer to perform the build. The output is shown in this figure:
3. Run an Example Application
The GCC tools require a J-Link debug interface. To update the OpenSDA firmware on your board to the latest J-Link app, visit www.nxp.com/opensda. After installing the J-Link OpenSDA application, download the J-Link driver and software package from www.segger.com/downloads.html.
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Connect the development platform to your PC via USB cable between the "SDAUSB" USB port on the board and the PC USB connector.
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Open the terminal application on the PC (such as PuTTY or TeraTerm) and connect to the debug COM port you determined earlier. Configure the terminal with these settings:
- 15200 baud rate
- No parity
- 8 data bits
- 1 stop bit
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Open the J-Link GDB Server application. Assuming the J-Link software is installed, the application can be launched by going to the Windows operating system Start menu and selecting "Programs -> SEGGER -> J-Link
J-Link GDB Server". -
Modify the settings as shown below. The target device selection chosen for this example is the “MK64FN1M0xxx12” and use the SWD interface.
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After it is connected, the screen should resemble this figure:
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If not already running, open a GCC Arm Embedded tool chain command window. To launch the window, from the Windows operating system Start menu, go to "Programs -> GNU Tools Arm Embedded
" and select "GCC Command Prompt". 
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Change to the directory that contains the demo application output. The output can be found in using one of these paths, depending on the build target selected:
/boards/ / / /armgcc/debug /boards/ / / /armgcc/release For this guide, the path is:
/boards/frdmke15z/demo_apps/hello_world/armgcc/debug -
Run the command "arm-none-eabi-gdb.exe
.elf". For this example, it is "arm-none-eabi-gdb.exe hello_world.elf". 
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Run these commands:
- "target remote localhost:2331"
- "monitor reset"
- "monitor halt"
- "load"
- "monitor reset"
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The application is now downloaded and halted at the reset vector. Execute the "monitor go" command to start the example application.
The hello_world application is now running and a banner is displayed in the terminal window.
