介绍通过使用Kinetis KL系列以及K系列通过不同方式驱动液晶。

The documentation is only for eFlexPWM module of KV58, it describes the feature of nano-edge PWM, the mechanism of nano-edge PWM, and give the waveform which can describe the feature of nano-edge PWM. The attachment includes the brief introduction of nano edge PWM, the waveform of nano edge PWM, and the code which runs on TWR-KV58 and KDS3.0. Original Attachment has been moved to: eFlexPWMNanoEdgeKV58_2.rar

UART Presentation (universal asynchronous receiver/transmitter) by Ali Piña, Freescale TIC. Module Explanation Connection Diagram Hands-On. Polling mode. Interrupt Mode. Presentación de UART  (universal asynchronous receiver/transmitter) by Ali Piña, Freescale TIC. a.       Explicación del modulo. b.      Diagrama de conexión. c.       Hands-On. Modo de Poleo Modo de Interrupción

The USB OTG module in Kinetis parts uses a Buffer Descriptor Table (BDT) in system memory to manage USB endpoint communications, the BDT is a a 512-byte buffer and there are 3 registers in USB module to contain the base address for it, and it must be 512-byte aligned otherwise there would be issue during transfer. In USB stack ver 4.1.1, some Kinetis old parts like K60N512, K20D72M have the demo project basked on CodeWarrior ARM compiler, and in khci_kinetis.c, bdt is defined as following: #define _BDT_RESERVED_SECTION_ #if(defined _BDT_RESERVED_SECTION_) #ifdef __CWCC__ #pragma define_section usb_bdt ".usb_bdt" RW __declspec(usb_bdt) uint_8_ptr bdt; but since the base address is defined as below: #define BDT_BASE               ((uint_32*)(bdt)) so the bdt definition is not correct , and we have to change it as below: #define _BDT_RESERVED_SECTION_ #if(defined _BDT_RESERVED_SECTION_) #ifdef __CWCC__ #pragma define_section usb_bdt ".usb_bdt" RW __declspec(usb_bdt) uint_8 bdt[512];//uint_8_ptr bdt; and the definition for usb_dbt section can be found in MK20X256_flash.lcf. with above modification, we can make the demo of "msd_mfs_generic" work well as expected. Please kindly refer to the following result got from TWR-K20D72M. FAT demo Waiting for USB mass storage to be attached... Mass Storage Device Attached ****************************************************************************** * FATfs DEMO * * Configuration:  LNF Enabled, Code page =1258 * ****************************************************************************** ****************************************************************************** * DRIVER OPERATION * ****************************************************************************** 1. Demo function: f_mount   Initializing logical drive 0...   Initialization complete ----------------------------------------------------------------------------- 2. Demo functions:f_getfree, f_opendir, f_readdir getting drive 0 attributes............... Logical drive 0 attributes: FAT type = FAT16 Bytes/Cluster = 2048 Number of FATs = 2 Root DIR entries = 512 Sectors/FAT = 250 Number of clusters = 63858 FAT start (lba) = 36 DIR start (lba,clustor) = 536 Data start (lba) = 568 ... 127716 KB total disk space. 127624 KB available. ----------------------------------------------------------------------------- ****************************************************************************** * DRECTORY OPERATION * ****************************************************************************** 1. Demo functions:f_opendir, f_readdir Directory listing...     ----A 2014/04/16 17:25     32253  tek00000.png     ----A 2014/04/16 17:34     31451  tek00001.png     ----A 2014/07/04 14:57     20549  tek00002.png     DR--- 2010/12/25 23:30         0 DIRECT~1     D---- 2010/01/01 00:00         0 DIRECT~2 3    File(s),     84253 bytes total 2    Dir(s) ----------------------------------------------------------------------------- 2. Demo functions:f_mkdir 2.0. Create <Directory_1> 2.1. Create <Directory_2> 2.2. Create <Sub1> as a sub directory of <Directory_1> 2.3. Directory list Directory listing...     ----A 2014/04/16 17:25     32253  tek00000.png     ----A 2014/04/16 17:34     31451  tek00001.png     ----A 2014/07/04 14:57     20549  tek00002.png     DR--- 2010/12/25 23:30         0 DIRECT~1     D---- 2010/01/01 00:00         0 DIRECT~2 3    File(s),     84253 bytes total 2    Dir(s) ----------------------------------------------------------------------------- 3. Demo functions:f_getcwd, f_chdir 3.0. Get the current directory     CWD: 0:/ 3.1. Change current directory to <Directory_1> 3.2. Directory listing Directory listing...     D---- 2010/01/01 00:00         0  .     D---- 2010/01/01 00:00         0  ..     D---- 2010/01/01 00:00         0  sub1 0    File(s),         0 bytes total 3    Dir(s) 3.3. Get the current directory     CWD: 0:/Directory_1 ----------------------------------------------------------------------------- 4. Demo functions:f_stat(File status), f_chmod, f_utime 4.1. Get directory information of <Directory_1>     DR--- 2010/12/25 23:30         0 Directory_1 4.2  Change the timestamp of Directory_1 to 12.25.2010: 23h 30' 20 4.3. Set Read Only Attribute to Directory_1 4.4. Get directory information (Directory_1)     DR--- 2010/12/25 23:30         0 Directory_1 ----------------------------------------------------------------------------- 5. Demo functions:f_rename Rename <sub1> to <sub1_renamed> and move it to <Directory_2> Directory listing...     D---- 2010/01/01 00:00         0  .     D---- 2010/01/01 00:00         0  ..     D---A 2010/01/01 00:00         0 SUB1_R~1 0    File(s),         0 bytes total 3    Dir(s) ----------------------------------------------------------------------------- 6. Demo functions:f_unlink Delete Directory_1/sub1_renamed Directory listing...     D---- 2010/01/01 00:00         0  .     D---- 2010/01/01 00:00         0  .. 0    File(s),         0 bytes total 2    Dir(s) ****************************************************************************** * FILE OPERATION * ****************************************************************************** 1. Demo functions:f_open,f_write, f_printf, f_putc, f_puts, fclose 1.0. Create new file <New_File_1> (f_open)     File size =    0 1.1. Write data to <New_File_1>(f_write) 1.2. Flush cached data     File size =   52 1.3. Write data to <New_File_1> (f_printf) 1.4. Flush cached data     File size =  103 1.5. Write data to <New_File_1> (f_puts) 1.6. Flush cached data     File size =  152 1.7. Write data to <New_File_1> uses f_putc function 1.8. Flush cached data     File size =  199 1.9. Close file <New_File_1> ----------------------------------------------------------------------------- 2. Demo functions:f_open,f_read, f_seek, f_gets, f_close 2.0. Open <New_File_1> to read (f_open) 2.1. Get a string from file (f_gets)     Line 1: Write data to  file uses f_write function 2.2. Get the rest of file content (f_read)     Line 2: Write data to file uses f_printf function Line 3: Write data to file uses f_puts function Line 4: Write data to file uses f_putc functionûöF¬ â•:7Rz}™ yzjw8¸×áÀ—»ÃЭ¹òÍ­ ä‹Hïk¨Wã½c'     ²7këÞÑ%VrC×»Ô¼ÒSÈÑèR+NjD¡¾òû>ú3‰SËþo^ÎI Pë±ñ‰þ/Directory_1[1] 2.3. Close file (f_close) ----------------------------------------------------------------------------- 3. Demo functions:f_stat, f_utime, f_chmod 3.1. Get  information of <New_File_1> file (f_stat)     ----A 2010/01/01 00:00       199  New_File_1.dat 3.2  Change the timestamp of Directory_1 to 12.25.2010: 23h 30' 20 (f_utime) 3.3. Set Read Only Attribute to <New_File_1> (f_chmod) 3.4. Get directory information of <New_File_1> (f_stat)     -R--A 2010/12/25 23:30       199  New_File_1.dat 3.5. Clear Read Only Attribute of <New_File_1> (f_chmod) 3.6. Get directory information of <New_File_1>     ----A 2010/12/25 23:30       199  New_File_1.dat ----------------------------------------------------------------------------- 4. Demo functions:f_ulink Rename <New_File_1.dat> to  <File_Renamed.txt> Directory listing...     D---- 2010/01/01 00:00         0  .     D---- 2010/01/01 00:00         0  ..     ----A 2010/12/25 23:30       199  FILE_R~1.TXT 1    File(s),       199 bytes total 2    Dir(s) ----------------------------------------------------------------------------- 5. Demo functions:f_truncate Truncate file <File_Renamed.txt> 5.0. Open <File_Renamed.txt> to write 5.1. Seek file pointer     Current file pointer:    0     File pointer after seeking:  102 5.2. Truncate file     File size =  102 5.3. Close file ----------------------------------------------------------------------------- 6. Demo functions:f_forward 6.0. Open <File_Renamed.txt> to read 6.1. Forward file to terminal Line 1: Write data to  file uses f_write function Line 2: Write data to file uses f_printf function 6.2. Close file ----------------------------------------------------------------------------- 7. Demo functions:f_ulink Delete <File_Renamed.txt> Directory listing...     D---- 2010/01/01 00:00         0  .     D---- 2010/01/01 00:00         0  .. 0    File(s),         0 bytes total 2    Dir(s) *------------------------------ DEMO COMPLETED    ------------------------ * ******************************************************************************

Kinetis M0+ FAQ文档的版本更新历史： Version 1: Basic structure; Version 2: Add 2 items Top highlights, 7 items Common and 7 items Tools; Version 3: add "Cyclone Max 使用步骤及注意事项"; Version 4,5,6: Adjust the FAQ structure; Version 7: Add "Kinetis L 、E、V、M系列选型指南"; Version 8: Add "开源工具"; Version 9: Add "Kinetis SDK"; Version 10,11,12: Add "智能插座"; Version 13: Add “FAQ使用规范” and "Kinetis Bootloader", and Readjust the "参考设计与方案"; Version 14, 15: Add the new motor control solution link into the "参考设计与方案"; Version 16: Add Blogs to "常用网站资料"; Version 17: Push the Kinetis M0+ FAQ Version log histors' information into subpage of "Kinetis M0+ FAQ 版本更新历史"; Version 18: Add "飞思卡尔MAPS开发板资料" into "常用网站资料"; Version 19: Replace "iBeacon" with "BLE"; Version 20, 21: Remove "WIFI" solution, Add "SPI接口读写SD卡"; Version 22: Rename "软件和例程" with "软件和文档", Add "常用的应用笔记" into "软件和文档" list; Click here to return to Kinetis M0+ FAQ main page...​

Hi everybody, The original document was moved to KSDK subspace. You can find it in the next link: https://community.freescale.com/docs/DOC-102612 Regards, Carlos

There is a popular WIFI platform called “GoKit” in China. This testing kit can be use to do some customized application. Not only WIFI communication, kit also support other functions. You can find interfaces listed as below. GoKit Interfaces: I try to use FRDM-KL02 to communicate with this kit to do a WIFI communication application. Board connection as below. This platform has two running mode. One is AirLink mode, and another is normal running mode. AirLink mode is used to WIFI communication or pair. Go to AirLink mode steps: Power on FRDM-KL02 Long press key1 to reset WIFI module. Wait until RED led on. Short press Key2 to go into configuration mode, wait until RED led flash on WIFI module. Open demo APP, select “adding device”, input SSID password. Waiting for configuration finish. Command Format HOF: 2bytes, value 0xFFFF Length: 2bytes Cmd:1byte SN:1byte Flags:2bytes DATA: Xbytes Checksum:1byte WIFI acquire device information MCU inform WIFI into configure mode MCU reset WIFI WIFI inform MCU status WIFI ask for reset Illegal command For detail code, I will post another thread for your reference.

Freescale Semiconductor is to demonstrate its Kinetis L series microcontrollers (MCUs) built on the ARM Cortex-M0+ processor at DESIGN West in San Jose, California, with alpha sampling due to start in the second quarter of 2012. Freescale  says the ability to demonstrate these devices is possible due to its  close partnership between ARM during the Cortex-M0+ core development  process and as a lead partner provided  input that helped ARM define and  develop the processor. The devices are slated for applications  such as domestic appliances, portable medical systems, smart meters,  lighting, power and motor control systems. "Our close partnership  with ARM throughout the design and development of their new core has  positioned us as the first MCU supplier to produce and demonstrate an MCU based on the Cortex-M0+ and continues our strategy of driving to  market new products based on the ARM architecture," said Reza  Kazerounian, senior vice president and general manager of Freescale’s  Automotive, Industrial and Multi-Market Solutions Group. Mike  Inglis, executive vice president and general manager of ARM’s Processor  Division, added "With the addition of the L series to their Kinetis  line, Freescale is creating one of the industry’s broadest, most  scalable ARM Cortex-M MCU portfolios, ranging from very low-cost,  entry-level products based on the ARM Cortex-M0+ processor, up to 4 MB,  200 MHz devices based on the Cortex-M4 processor." Manufactured  using Freescale’s low-leakage, 90 nm thin film storage (TFS) process  technology, the Kinetis L series will have a selection of on-chip flash  memory densities and analog, connectivity and HMI peripheral options. Upward  migration through the Kinetis portfolio is available via compatible Kinetis K series devices (built on the ARM Cortex-M4 processor) that  provide access to DSP performance and advanced feature integration. The  ARM Cortex-M0+ processor includes a reduced two-stage pipeline,  allowing faster branch instruction execution, single-cycle access to I/O  and critical peripherals, optimized access to program memory, linear 4  GB address space that removes the need for paging, reducing software  complexity and ensuring a more 8-bit-like user experience and a micro  trace buffer, providing a low-cost trace solution that allows faster bug  identification and correction without the need for additional I/O  resources. Freescale will demonstrate the ARM Cortex-M0+ core at its exhibition booth #1604 at DESIGN West , March 26-29 at the San Jose McEnery Convention Center.

The Technical University in Brasov (Romania) has set up a Medical Teaching lab featuring the Freescale Tower Kit K53 with Oximeter MED-SPO2 and 2 electrode system EKG MED-EKG. Find below the material associated to this lab led by Prof. Sorin-Aurel Moraru from the Faculty of Engineering. He can be contacted at smoraru@unitbv.ro The course is in Romanian and include an overview of the hardware and exercises

Using a MK70FN1M0VMJ15 processor with MII and ADC2_SE16 enabled. Also using Codewarrior 10.6 and MQX4.022. Anytime I initialize the ADC2_SE16 the webserver stops working. I have delayed the initialization of the ADC2_SE16 and found that webserver works fine till initialization. I have also noticed that when the ADC2_SE16 is initialized first the webserver never gets link active. My question is that even though these are different ports and no pin is shared could the possibly be affecting each other? Hi Lee: I have been looking for information related to this problem but at this moment I have not find anything, In this case I would like to know if you are using a development board from Freescale or if you are using a custom board? Have a nice day, Perla Moncada ----------------------------------------------------------------------------------------------------------------------- Note: If this post answers your question, please click the Correct Answer button. Thank you! ----------------------------------------------------------------------------------------------------------------------- It is a custom board, with MII setup instead of RMII. I am concerned that it may be a chip issue, and have no real way to test that possibility with the Development board. This document was generated from the following discussion: 

Overview          KBOOT v2.0 had been released in the Q2 of the 2016 and it has a lot of new features versus the previous version. For instance, the USB peripheral can work as Mass Storage Class device mode now, not just only supports the HID interface. And in following, USB MSD Bootloader implementation will be illustrated. Preparation FRDM-K64F board Fig1 FRDM-K64F KBOOT v2.0 downloading: KBOOT v2.0 IDE: IAR v7.50 Application demo: KSDK v2.0   Flash-resident bootloader           The K64_120 doesn’t contain the ROM-based bootloader, so the flash-resident bootloader need to be programmed in the K64 and the flash-resident bootloader can be used to download and program an initial application image into a blank area on the flash, and to later update the application.         I. Open the the bootloader project, for instance, using the IAR and select the freedom_bootloader demo         The Fig 2 illustrates the bootloader project for K64 which resides in ~\NXP_Kinetis_Bootloader_2_0_0\NXP_Kinetis_Bootloade r_2_0_0\targets\MK64F12. Fig 2      II. After compiles the demo, then clicks the  button to program the demo to the K64 Linker file modification       According to the freedom_bootloader demo, the vector table relocation address of the application demo has been adapted to the 0xa000 (Table 1), however the default start address of the application is 0x0000_0000. So it’s necessary to modify the linker file to fit the freedom_bootloader and the Table 2 illustrates what the modifications are.                                                     Table 1 // The bootloader will check this address for the application vector table upon startup. #if !defined(BL_APP_VECTOR_TABLE_ADDRESS) #define BL_APP_VECTOR_TABLE_ADDRESS 0xa000 #endif                                                   Table 2 define symbol __ram_vector_table_size__ = isdefinedsymbol(__ram_vector_table__) ? 0x00000400 : 0; define symbol __ram_vector_table_offset__ = isdefinedsymbol(__ram_vector_table__) ? 0x000003FF : 0; //define symbol m_interrupts_start       = 0x00000000; //define symbol m_interrupts_end         = 0x000003FF; define symbol m_interrupts_start       = 0x0000a000; define symbol m_interrupts_end         = 0x0000a3FF; //define symbol m_flash_config_start     = 0x00000400; //define symbol m_flash_config_end       = 0x0000040F; define symbol m_flash_config_start     = 0x0000a400; define symbol m_flash_config_end       = 0x0000a40F; //define symbol m_text_start             = 0x00000410; define symbol m_text_start             = 0x0000a410; define symbol m_text_end               = 0x000FFFFF; define symbol m_interrupts_ram_start   = 0x1FFF0000; define symbol m_interrupts_ram_end     = 0x1FFF0000 + __ram_vector_table_offset__; define symbol m_data_start             = m_interrupts_ram_start + __ram_vector_table_size__; define symbol m_data_end               = 0x1FFFFFFF; define symbol m_data_2_start           = 0x20000000; define symbol m_data_2_end             = 0x2002FFFF; /* Sizes */ if (isdefinedsymbol(__stack_size__)) {   define symbol __size_cstack__        = __stack_size__; } else {   define symbol __size_cstack__        = 0x0400; } if (isdefinedsymbol(__heap_size__)) {   define symbol __size_heap__          = __heap_size__; } else {   define symbol __size_heap__          = 0x0400; } define exported symbol __VECTOR_TABLE  = m_interrupts_start; define exported symbol __VECTOR_RAM    = isdefinedsymbol(__ram_vector_table__) ? m_interrupts_ram_start : m_interrupts_start; define exported symbol __RAM_VECTOR_TABLE_SIZE = __ram_vector_table_size__; define memory mem with size = 4G; define region m_flash_config_region = mem:[from m_flash_config_start to m_flash_config_end]; define region TEXT_region = mem:[from m_interrupts_start to m_interrupts_end]                           | mem:[from m_text_start to m_text_end]; define region DATA_region = mem:[from m_data_start to m_data_end]                           | mem:[from m_data_2_start to m_data_2_end-__size_cstack__]; define region CSTACK_region = mem:[from m_data_2_end-__size_cstack__+1 to m_data_2_end]; define region m_interrupts_ram_region = mem:[from m_interrupts_ram_start to m_interrupts_ram_end]; define block CSTACK    with alignment = 8, size = __size_cstack__   { }; define block HEAP      with alignment = 8, size = __size_heap__     { }; define block RW        { readwrite }; define block ZI        { zi }; initialize by copy { readwrite, section .textrw }; do not initialize  { section .noinit }; place at address mem: m_interrupts_start    { readonly section .intvec }; place in m_flash_config_region              { section FlashConfig }; place in TEXT_region                        { readonly }; place in DATA_region                        { block RW }; place in DATA_region                        { block ZI }; place in DATA_region                        { last block HEAP }; place in CSTACK_region                      { block CSTACK }; place in m_interrupts_ram_region            { section m_interrupts_ram }; SB file generation     I. Brief introduction of SB file         The Kinetis bootloader supports loading of the SB files. The SB file is a Freescale-defined boot file format designed to ease the boot process. The file is generated using the Freescale elftosb tool. The format supports loading of elf or srec files in a controlled manner, using boot commands such as load, jump, fill, erase, and so on. The boot commands are prescribed in the input command file (boot descriptor .bd) to the elftosb tool. The format also supports encryption of the boot image using AES-128 input key.          And right now, the USB MSD bootloader only support SB file drag and drop.    II. Generate the BIN file         After open the hello_world demo in the IAR, using project options dialog select the "Output Converter" and change the output format to "binary" for outputting .BIN format image (Fig 3). Next, build the application demo, then the .BIN file will be generated after the building completes. Fig 3      III. Create BD file There is a template BD file which resides in the ~\NXP_Kinetis_Bootloader_2_0_0\NXP_Kinetis_Bootloader_2_0_0\apps\led_demo\src. Next, adapt the BD file by referring to the Kinetis Elftosb User's Guide, the following table shows the BD file content.                                                    Table 3 sources {         # BIN File path         myBINFile = "hello_world.bin"; } section (0) {         #1. Erase the internal flash         erase 0x0000a000..0x0010000;         #2. Load BIN File to internal flash         load myBINFile > 0xa000;         #3. Reset target.         reset; }      IV.  SB file generation          After creating the BD file shown in the following figure, copy the "hello_world.bin", elftosb.exe, and the BD file into the same directory. Then, open the window with command prompt and invoke elftosb such as “elftosb –V –c FRDM-K64F.bd –o image.sb”. The elftosb processes the FRDM-K64F.bd file and generates an image.sb file. Elftosb also outputs the commands list as shown in Fig 4. Fig 4     V. Application code updating       Plug a USB cable from the PC to the USB connector J26 to power the board , then keep holding the button SW2 down until press and release the Reset button SW1, it can force the K64_120 enter the BOOTLOADER mode. Next, plug another USB cable from the PC to the USB connector J22 (Fig 5), the FSL Loader will come out after completes the enumeration and it will appear as a removable storage driver (Fig 6).  Copy & paste or drag & drop the image.sb to the FSL Loader drive to update the application code, and the Fig 7 illustrates the result of application code runs. Fig 5 Fig 6 Fig 7

Here you will find both the code and project files for the USB Mouse project. In this project the USB module is configured as a device, the X and Y coordinates to move the cursor are obtained from the accelerometer measurements. Once the code is loaded it is necessary to disconnect the USB cable from the J26 USB connector and plug it to the K64 USB connector. Once the device enumerates you can use it as an air mouse. The left and right click buttons have not been enabled. To compile the project you must import the following libraries: USBMouse.h FXOS8700Q.h Code: #include "mbed.h" #include "USBMouse.h" #include "FXOS8700Q.h" //I2C lines for FXOS8700Q accelerometer/magnetometer FXOS8700Q_acc acc( PTE25, PTE24, FXOS8700CQ_SLAVE_ADDR1); USBMouse mouse; int main() {     acc.enable();     float faX, faY, faZ;     int16_t x = 0;     int16_t y = 0;       while (1)     {         //acc.getAxis(acc_data);         acc.getX(&faX);         acc.getY(&faY);         x = 10*faX;         y = 10*faY;               mouse.move(x, y);         wait(0.001);     } }

在电机控制，Audio等很多应用中，我们经常会用到一些常见的正余弦，矩阵变换，FFT等一些DSP函数，提到DSP库，通常会想到使用ARM 公司提供的 CMSIS 库。CMSIS 库是ARM和一些半导体厂家针对Cortex-M系列制定的一套接口标准，包括针对内核操作的CMSIS-CORE API，针对DSP应用的CMSIS-DSP Library，针对RTOS的CMSIS-RTOS API，与外设接口的CMSIS-SVD以及提供Debug访问接口的CMSIS-DAP。 其中，又以DSP应用的CMSIS-DSP 库的应用最为广泛。针对Cortex-M4中的DSP功能，CMSIS-DSP部分提供了超过60多种功能的DSP算法库，尤其是随着Cortex-M4中集成了FPU硬件单元，CMSIS-DSP 库的应用也越来越广泛。 在KEIL 和IAR中都集成了对CMSIS的支持，然而在CodeWarrior中没有直接支持CMSIS，需要用户移植到自己的CW工程中，所以就需要使用者了解CMSIS的结构，手动添加库文件和头文件，并完成一些重要的编译参数配置。特别是有些芯片支持FPU浮点运算单元，有些不支持，在配置选项上差别很大。在飞思卡尔Kinetis系列芯片中，FPU浮点运算单元也是一个可选的部件，只有在名称中带有FN和FX的芯片才支持FPU硬件浮点功能，如MK60FN1M0, MK60FX512。本文档分别介绍在使用和不使用FPU的情况下如何一步步移植CMSIS的DSP库到自己的CodeWarrior工程中。 需要注意的是 FPU 单元是指的芯片上的一个独立于 CPU 处理的浮点运算单元，整个单元在大多数厂家的芯片中都是可以被使能和关闭的。相对于芯片，编译器也设置了相应的 FPU 功能开启/关闭的选项，在编译时需要告诉编译器是否开启 FPU 功能。编译器一旦开启 FPU 功能，在处理单精度浮点运算的语句时就会用带 V-开头的汇编指令进行编译。如果编译器使能了 FPU 功能，而芯片未开启 FPU 单元，程序运行到浮点语句时就会出现异常。相反，如果编译器未使能 FPU 功能，芯片即使开启了 FPU单元，程序还是会按照未使能 FPU 的代码进行处理。在本例程中，为对比分析是否采用FPU的编译指令差别以及在板的执行效率，选用Kinetis K70FN1M为实验对象。 硬件平台：TWR-K70F120M核心板      软件环境：CodeWarrior v10.5        CMSIS版本 ：V3.2 一. 准备工作： 下载CMSIS的库，当前最新的版本为V3.2，解压后名称为CMSIS-SP-00300-r3p2-00rel1，其目录结构如下图。分别包含CMSIS-DSP, CMSIS-RTOS和CMSIS-SVD的库文件。在本Cortex M4的CMSIS-DSP的应用中，真正用到的文件包括CMSIS\Include中CM4相关的头文件，CMSIS\Lib\GCC文件夹中的库文件libarm_cortexM4l_math.a(软浮点)和libarm_cortexM4lf_math.a(硬浮点)，以及Device\ARM\ARMCM4\include中外设访问相关的两个头文件。 二. 不使用K70的FPU浮点运算单元，移植CMSIS的DSP库到CW的步骤；      Step 1:    新建一个Baremental的工程，选择器件器件MK70FN1M0（支持硬件FPU）；     Step 2:    选择Floating Point浮点运算实现的类型，即指定编译器将C代码编译成汇编代码时使用的规则； 在Floating Point四个选项含义如下： Software选项：表示不使用FPU硬件，而是使用GCC的整数算术运算来模拟浮点运算； Handware(-mfloat –abi=hard) 选项：表示使用FPU硬件来进行浮点运算，函数的参数直接传递到FPU的寄存器(s0-d0)中； Handware(-mfloat –abi=softfp)选项：表示使用FPU硬件来进行浮点运算，但是函数的参数传递到整数寄存器(r0-r3）中，然后再传递到FPU中； Handware(-mfloat –abi=softfp –fshort -double)选项：其配置项同上，只不过使能了fshort  double功能，并且此处的double数据的宽度等同于float； 有兴趣研究各个选项意义的可以参考CW for MCU技术文档的第3章，在本例程中使用的是软浮点，所以选择Software项。需要注意的是：此配置选项仅出现支持FPU硬件单元的芯片工程中，如MK60FN1M0, MK60FX512等，否则默认没有此选项，默认为软件浮点。 Step 3:    点击“Next”进入下图，选择使用Processor Expert，点击“Finish“完成工程的建立； Step 4:    进入当前工程的文件夹，新建文件夹CMSIS，从之前在准备步骤解压的CMSIS文件包\...\CMSIS-SP-00300-r3p2-00rel1\CMSIS中拷贝Include和Lib文件夹到当前工程新建的CMSIS文件夹。另外，拷贝\...\CMSIS-SP-00300-r3p2-00rel1\Device\ARM\ARMCM4\Include中的ARMCM4.h和system_ARMCM4.h到当前工程新建的CMSIS文件夹中； Step 5:    回到CodeWarrior主界面选择新建的工程文件，F5刷新可以看到CMSIS出现在工程文件中。其中Include是CMSIS库的一些头文件，包括M0+/M3/M4的一些头文件；在Lib文件中是已经编译好的库文件，ARM文件夹是使用在KEIL IDE中的库文件，G++文件夹是使用在IAR中的库文件，而由于当前CW工程使用的GCC的编译器，所以GCC文件夹才是CW需要的，因此，为缩减工程大小可以删除ARM和G++文件夹；     Step 6:    打开工程属性框，选择Target Processor的Float ABI为No FPU； Step 7:    在GCC Complier的Defined symbols中添加编译的宏定义ARM_MATH_CM4； Step 8:    在GCC Complier的Include paths中添加CMSIS库的头文件，路径为：工程目录\CMSIS\Include； Step 9:    在GCC C Linker的Miscellaneous项的Other objects中指定使用的库文件(位于CMSIS\Lib\GCC文件夹中)。因为本例程中不使用FPU，所以选择libarm_cortexM4l_math.a，此处需要特别注意，否则编译会报错； Step 10: 在ProcessorExpert.c文件中添加代码； #include <math.h> #include "arm_math.h" #define DELTA    (0.000001f) const float32_t testRefOutput_f32 = 1.000000000; const float32_t radians=1.047197533333333; float32_t  cosOutput, sinOutput, diff; float32_t cosSquareOutput,sinSquareOutput,testOutput; int main(void) {   int m,n;   PE_low_level_init();   cosOutput = arm_cos_f32(radians); /*求正余弦*/                   sinOutput = arm_sin_f32(radians);                                 arm_mult_f32(&cosOutput, &cosOutput, &cosSquareOutput, 1); /*求积运算*/   arm_mult_f32(&sinOutput, &sinOutput, &sinSquareOutput, 1);               arm_add_f32(&cosSquareOutput, &sinSquareOutput, &testOutput, 1); /*求和运算*/   diff = fabsf(testRefOutput_f32 - testOutput);  /* 求绝对值 */                 if(diff > DELTA)   {                         while(1)                                 {                                   for(m=0;m<2000;m++)                                                 for(n=0;n<200;n++){};                                                 D7_NegVal();                                 }     }                 } Step 11:    编译并下载Debug，在  sinOutput = arm_sin_f32(radians);处设置断点，可以看到CMSIS-DSP库中的正余弦浮点数运算函数运算正常，其反汇编的得到为普通的ARM指令(FPU 单元汇编指令通常在普通指令前加字母V，仅在 FPU 功能被使能时使用)，完成一个正弦计算； 至此，完成了不使用K70的FPU浮点运算单元，移植CMSIS的DSP库到CW的步骤。     三.     使用K70的FPU浮点运算单元，移植CMSIS的DSP库到Codewarrior的步骤 使用K70的FPU硬件浮点运算单元，移植CMSIS的DSP库到Codewarrior的方法有两种：一种是按照上面软浮点的方式Step By Step的建立工程，步骤和上面二的步骤基本一致，主要的两个区别在于：(1). Step 2要选择Handware(-mfloat –abi=hard) 选项，(2). Step 9 改为libarm_cortexM4lf_math.a。另外一种就是在上面工程的基础上修改配置选项。鉴于方便，本教程采用第二种方案，完成在Codewarrior中调用CMSIS的DSP库，通过K70的FPU浮点运算单元执行浮点运算，即硬浮点。 Step 1:    打开工程属性对话框，选择Target Processor的Float ABI为FPU with hard vfp passing(-mfloat –abi=hard)； Step 2:    在GCC Complier的Defined symbols中添加编译的宏定义：_VFPV4； Step 3: 在GCC C Linker的Libraries项的library search path中指定链接的规则，把上面工程中默认的"${MCUToolsBaseDir}/ARM_GCC_Support/ewl/lib/armv7e-m"修改为 "${MCUToolsBaseDir}/ARM_GCC_Support/ewl/lib/armv7e-m/fpu"； Step 4:    在GCC C Linker的Miscellaneous项的Other objects中指定使用的库文件(位于CMSIS\Lib\GCC文件夹中)。因为本例程中使用FPU，所以选择libarm_cortexM4lf_math.a，此处需要特别注意，否则编译会报错； Step 5:    完成以上配置后，编译工程并下载调试（此处建议编译之前先Clean一下整个工程），同样，在  sinOutput = arm_sin_f32(radians);处设置断点，可以看到CMSIS-DSP库中的正余弦浮点数运算函数运算正常，其反汇编的得到为FPU指令(FPU指令通常是指在普通指令前加字母V，仅在 FPU功能被使能时使用)，并且在Register观察窗口中也多了个FPU寄存器列表，感兴趣的读者可以对比一下和前面实验汇编出代码的差异，此处不再赘述； 至此，分别完成了使用和不适用K70的FPU浮点运算单元情况下， CMSIS的DSP库到Codewarrior的移植。在实际应用中需要用到更多的DSP函数，在项目中直接调用即可。下一步， Just Enjoy The Convenience of  The CMSIS! 有一点需要说明的是，前文中讲到使用FPU单元需要两步设置：(1). 在编译器中开启相应的 FPU 功能选项；(2). 开启芯片FPU 单元。似乎我们前面的设置是完成了第一个步骤，然而第二个步骤呢？仔细查看_arm_atart.c文件，可以发现代码_fp_init()正是完成了开启芯片FPU单元的过程，如下图，是一个条件编译函数，这也就解释了为什么在上面Step 2中定义了_VFPV4，其本质也就是使能芯片的FPU单元，其具体实现可以查看ARM手册的第74页的描述。 #ifdef   __VFPV4__        //Step 2中的宏定义                 __fp_init();      // 开启芯片的FPU单元 #endif

When using ADCs it is not enough to just configure the module, add a clock signal, apply the Nyquist criteria and hope for the best, because normally that is just not enough. Even if we use the best software configuration, sampling rate, conversion time, etc; we might end up with noisy conversions, and worst of all a low ENOB figure which sums up in a lousy, low resolution ADC application. To complement the software end you need to follow some basic hardware design rules, some of them might seem logical, other might even weird or excessive however they are the key to a successful conversion, I took the time to compile a short list of effective design best practices trying to cover the basics of ADC design. If you think I missed something feel free to comment and ask for more information. Ground Isolation Because ground is the power return for all digital circuits and analog circuits, one of the most basic design philosophies is to isolate digital and analog grounds. If the grounds are not isolated, the return from the analog circuitry will flow through the analog ground impedance and the digital ground current will flow through the analog ground, usually the digital ground current is typically much greater than the analog ground current.  As the frequency of digital circuits increases, the noise generated on the ground increases dramatically. CMOS logic families are of the saturating type; this means the logic transitions cause large transient currents on the power supply and ground. CMOS outputs connect the power to ground through a low impedance channel during the logic transitions. Digital logic waveforms are rectangular waves which imply many higher frequency harmonic components are induced by high speed transmission lines and clock signals.                              Figure 1: Typical mixed signal circuit grounding                              Figure 2: Isolated mixed signal circuit grounding Inductive decoupling Another potential problem is the coupling of signal from one circuit to another via mutual inductance and it does not matter if you think the signals are too weak to have a real effect, the amount of coupling will depend on the strength of the interference, the mutual inductance, the area enclosed by the signal loop (which is basically an antenna), and the frequency. It will also depend primarily on the physical proximity of the loops, as well as the permeability of the material. This inductive coupling is also known as crosstalk in data lines.                               Figure 3: Coupling induced noise It may seem logical to use a single trace as the return path for the two sources (dotted lines). However, this would cause the return currents for both signals to flow through the same impedance, in addition; it will maximize the area of the interference loops and increase the mutual inductance by moving the loops close together. This will increase the mutual noise inductance and the coupling between the circuits. Routing the traces in the manner shown below minimizes the area enclosed by the loops and separates the return paths, thus separating the circuits and, in turn, minimizing the mutual noise inductance.                               Figure 4: Inductance decoupling layout Power supply decoupling The idea after power decoupling is to create a low noise environment for the analog circuitry to operate. In any given circuit the power supply pin is really in series with the output, therefore, any high frequency energy on the power line will couple to the output directly, which makes it necessary to keep this high frequency energy from entering the analog circuitry. This is done by using a small capacitor to short the high frequency signals away from the chip to the circuit’s ground line. A disadvantage of high frequency decoupling is it makes a circuit more prone to low frequency noise however it is easily solved by adding a larger capacitor. Optimal power supply decoupling A large electrolytic capacitor (10 μF – 100 μF) no more than 2 in. away from the chip. A small capacitor (0.01 μF – 0.1 μF) as close to the power pins of the chip as possible. A small ferrite bead in series with the supply pin (Optional).                               Figure 5: Power supply decoupling layout Treat signal lines as transmission lines Although signal coupling can be minimized it cannot be avoided, the best approach to effectively counteract its effects on signal lines is to channel it into a conductor of our choice, in this case the circuit’s ground is the best choice to channel the effects of inductive coupling; we can accomplish this by routing ground lines along signal lines as close as manufacturing capabilities allow. An very effective way to accomplish this is routing signals in triplets, these works for both digital and analog signals.The advantages of doing so are an improved immunity not only to inductive coupling but also immunity to external noise. Optimal routing: Routing in “triplets” (S-G-S) provide good signal coupling with relatively low impact on routing density Ground trace needs to be connected to the ground pins on the source and destination devices for the signal traces Spacing should be as close as manufacturing will allow                               Figure 6: Transmission line routing Signal acquisition circuit To improve noise immunity an external RC acquisition circuit can be added to the ADC input, it consists of a resistor in series with the ADC input and a capacitor going from the input to the circuit’s ground as the figure below shows:                                                             Figure 7: ADC with an external acquisition circuit The external RC circuit values depend on the internal characteristics and configuration of the ADC you use, such as the availability of an internal gain amplifier or the ADC’s architecture; the equation and circuit shown here represents a simplified form of ADC used in Freescale devices. The equivalent sampling resistance RSH is represented by total serial resistance connected between sampling capacitance and analog input pin (sampling switch, multiplexor switches etc.). The sampling capacitance CSH is represented by total parallel capacitance. For example in a case of Freescale SAR ADC equivalent sampling capacitance contains bank of capacitances. The equation shown how to calculate the value of the input resistor based on the values of both the input and sample and hold circuit. It must be noted the mentioned figures could have an alternate designation in any given datasheet; the ones mentioned here are specific to Kinetis devices: TAQ=      Acquisition time (.5/ADC clock) CIN=       Input capacitance (33pF min) CSH=      Sample & Hold circuit capacitance ( CDAIN in datasheet) VIN=       Input voltage level VCSH0= Initial voltage across S&H circuit (0V) VSFR=    Full scale voltage (VDDA) N=           bit resolution Note:  Special care must be taken when performing the calculation since a deviation from the correct values will result in a significant conversion error due to signal distortion.

To do: Implement a program that lets the 4 LEDs on the Tower toggle all together using the PIT Interrupt. This time, let the program run in the Flash. * toggle period 0.5 s * extract vector table and service routines in 'vector.c' * Change the linker command file 'ldscript_flash' * Take care of the 16 Byte security settings from $400-$410 in the Flash. Do not overwrite!!! Hint: Use the 'arm_cm4.c and 'arm_cm4.h' from the freescale kinetis homepage, which include access functions for the NVIC. For ease of use, these routines are included in the result file. Result: TWR_K60_PIT0_Flash.zip

The Kinetis family has abundant low power mode. Customers may confused to figure out the different way to wake up from the low power mode. 1)  In VLPR, VLPW:  the NVIC remains sensitive to interrupts, so any interrupt will be serviced. 2)  In Stop, VLPS:  the device can be waked up by USB wake up interrupt only. 3)  In LLS, VLLSx:  the device won't be able to wake up from any USB source. 4)  LLWU is used to wake up, so customer would able to wake up from any of the available LLWU wake up sources. As for the USB module, there has two different interrupts for a USB resume event. One asynchronous to be able to wake from a low power mode, which is triggered by change in the state of the USB lines. The other is synchronous and is triggered only after 2.5 us of detecting a K state (D+ = 0, D- = 1, for Full Speed). The application is responsible to transition to the low power mode whenever it requires it, and for this purpose it must check the device state as reported by the USB stack. When a suspend condition is detected in the bus, the SLEEP interrupt triggers and the stack changes its state to suspend; then the application will transition to the low power mode. When this SLEEP interrupt occurs, the asynchronous wake interrupt is enabled, and is disabled when it is triggered (this is required by the module to clear the interrupt). In normal conditions, the synchronous resume interrupt or the reset interrupt will be triggered afterwards, causing the stack to transition its state to other than suspend. The application can then know that communication is active again and will avoid entering the low power mode again.

1. 使用J-Link+J-Flash给Kinesis烧写序列号（Program serial number for Kinetis by J-Link + J-Flash） 2. 教你用J-Flash ARM工具单独烧写程序到Kinetis 3. Cyclone Max 使用步骤及注意事项 4. 飞思卡尔常用脱机烧写工具 5. 离线烧写工具Cyclone Max使用方法及单次按键烧写两个image文件的实现方法​ 6.Kinetis 量产注意事项​

Table of Contents 1       Introduction 2       DMA to emulate ADC Flexible Scan. 2.1         System overview and flow diagram for Flexscan. 3       SDK implementation. 3.1         ADC configuration. 3.2         LPMTR configuration 3.3         DMA configuration 4       ADC Flex Scan mode with DMA Appendix A: Requirements Reference   1    Introduction This document describes how to combine ADC, DMA and a timer to implement a ADC Flexible storing data with SDK 2.2 and MCUXpresso IDE. In this configuration ADC measures will be stored into an internal memory buffer with DMA, which imply, no CPU. With this configuration MCU uses less resources, only using ADC and DMA (2 channels) and a timer to trigger conversions. This way, the MCU does not need to read the ADC result register, because the memory management will be done by DMA automatically.   To implement this application we will use SDK libraries, which includes ADC and DMA libraries. The timer used to trigger ADC conversion will be the LPTMR. MCUXpresso IDE will be used as development environment, please check Appendix A to look where you can download SDK libraries and IDE. The project will be created from scratch, regardless of this, MCUXpresso IDE and SDK libraries allows us to create a project with some headers and libraries in the project, if you have problems creating a new project in MCUXpresso please check Reference 4.   In this document we will use the FRDM-K64F which is an ultra-low-cost development platform, but this implementation could be easily migrated to any kinetis family that support second-generation eDMA module (enhanced Direct Memory Access).   This document is an update of the community doc: Using DMA to Emulate ADC Flexible Scan Mode with KSDK  which uses old SDK libraries.   2     DMA to emulate ADC Flexible Scan   Flexible scan implementation needs 2 types of data movement: ADC measures (from peripheral to internal memory) and ADC mux change (from internal memory to peripheral). Second one is needed to change ADC input channel and have the flexible implementation, first one save ADC measures in our internal memory.   DMA peripheral (for this MCU) includes up to 16 channels, for this application we will only use 2 channels, one for ADC measures and one for ADC muxing channel. It is important to remark that we will use the linking feature in these channels to implement the ADC changing channel automatically, later in this document it will be explain this feature.   2.1         System overview and flow diagram for Flexscan.   As already mentioned, this implementation will use one DMA channel to transfer data from ADC measures (ADC0_RA register in this case) to a memory buffer (named here as g_ADC0_resultBuffer), so follow figure shows this movement:     As you can see, ADC0_COCO (conversion complete) will be the one that request a transfer from ADC0_RA to resultBuffer. Once this transfer has completed, we need to change ADC channel, so when DMA channel 1 transfer finishes, it will indicate us to trigger the other data movement, in this case from internal buffer g_ADC_mux (that save our adc channels) to the ADC0_SC1A register that sets the ADC channel, so the following diagram shows this.     To do this, this application used a DMA feature that link DMA channels, channel-to-channel linking. So, when one DMA channel finished, the linked DMA channel will be triggered, in this case when DMA channel 1 has completed to move data from ADC measure register to internal memory then DMA channel 0 need to be triggered to change the ADC channel, so next conversion ADC would have selected other ADC channel.   Once that the ADC channels is changed (and the HW trigger happens), the COCO flag from ADC will trigger other DMA request in channel 0 and the process will start again. This flow process can be repeated as many channels as we have and as many samples as we want, for this example code we will measure 3 channels and have 4 samples, so the result buffer size is 3 × 4 = 12 (the real buffer size is 16, to demonstrate that only 12 data field parts are written).   The ADC works in hardware trigger mode, with the LPTMR timer working as the trigger source. This mean that even though DMA channel 0 changed the ADC input channel, conversion will not start until HW trigger (LPTMR) start the conversion, this mean that the flow of the program can be as follow.       In the example code provided, when DMA channel 0 has changed 3 times the ADC channel, DMA channel 1 major loop will happen, and when the sample X is the last sample (sample 4) of the last channel in muxbuffer, then Major loop in DMA channel 0 happens and the application ends (or it could start again). This mean that the application here can be shown as:             3     SDK implementation   Implementation of this code can be dived in three parts; LPTMR, ADC and DMA configuration.   3.1         ADC configuration       ADC configuration is a normal ADC config, with 12 single ended, Asynchronous clock source and Vref as reference voltage. Hardware trigger and DMA support are enable to trigger conversions with LPTMR and to be able to trigger a DMA request when COCO interrupt happen. In ADC channel configuration, it is enable Conversion completed interrupt and it is loaded the value of g_ADC_mux to channel number, this will be the first channel that LPTMR will trigger.   3.2         LPMTR configuration       LPMTR is a common configuration with LPTMR as time counter. Please notice that prescaler could be used and select a prescaler clock. To set LPTMR period it is used the macro USEC_TO_COUNT, which just take the value in microseconds and it calculate the number of ticks to count, using the source clock. Also at the end, LTPMR is configured to be used as HW trigger for ADC conversions in the SIM register.   3.3         DMA configuration     For DMAMUX configuration it is enable Channel 0 and 1 and it is selected the source trigger, DMA for channel 0 (it will be triggered with linking feature) and ADC COCO flag for channel 1 (trigger when the ADC conversion complete).     For DMA configuration, it is needed to create 2 tcd configuration, there are set in transferConfig_chx. First one defined is for DMA channel 1 (data from ADC measure to internal memory), and the second is for DMA channel 0 (data from internal memory to ADC_SC1 register to change ADC channel). Please noticed that these definitions are in bytes to transfer, so some of them are sizeof(uint16_t). Here is also the setup to link channel 1 to channel 0.       Finally, it is added the adjustment for TCD, so when DMA major loop finished in both, it will point to the start of the source and destination. Noticed that this is added just for internal memory address, this is because for the case of a peripheral (ADC in this case), pointer to address doesn’t change.   Then DMA channel 1 and LPTMR are started.   When DMA channels were initialized, their callbacks were also defined;     This flags are just used for this implementation and as reference, they can be removed if needed. After Major loop has finished, SDK implementation disable DMA transfers automatically, so noticed that the callback_1 for DMA channel 1 has a line commented, that if uncommented, this application will act as a ADC that load measurements in an internal Ring buffer Indefinitely.   4     ADC Flex Scan mode with DMA With a basic Print implementation of ADC results we can show the functionality of this example project.     There are obtained the following results,         Appendix A: Requirements Download page for MCUXpresso IDE: MCUXpresso IDE|NXP  Download page for SDK 2.x drivers: Welcome to MCUXpresso | MCUXpresso Config Tools  Go to Build an SDK, select your device and click on Specify Additional Configuration Settings, verify that you have selected KDS as toolchain and then Go to SDK Builder. Click in Download Now, accept Term and conditions and download SDK packet. Please check: Generating a downloadable MCUXpresso SDK v.2 package    References   Using DMA to Emulate ADC Flexible Scan Mode with KSDK  MCUXpresso IDE: Unified Eclipse IDE for NXPs ARM Cortex-M Microcontrollers | MCU on Eclipse  https://www.nxp.com/docs/en/application-note/AN4590.pdf  Creating New Projects using installed SDK Part Support, MCUXpresso_IDE_User_Guide.pdf  

Este proyecto se hizo teniendo en mente el consumo del agua en un hogar promedio para ayudar a no desperdiciarla; en un caso típico se tiene una cisterna a la que llega el agua directamente de la red de agua potable de la ciudad, también se cuenta con un tinaco y con una bomba de agua para trasladarla desde la cisterna. Tanto el tinaco como la cisterna cuentan con 2 sensores de nivel de agua, un nivel alto y un nivel bajo... Por dar un ejemplo, cuando la cisterna se encuentre totalmente llena y el tinaco vacío, la bomba encenderá para enviar agua al tinaco y continuará subiendo agua hasta que el sensor alto del tinaco detecte que ya está lleno y entonces se apagará la bomba; cuando el tinaco empiece a vaciarse y el nivel alto no detecte agua la bomba no encenderá, lo hará hasta que el nivel bajo del tinaco no detecte agua, de ésta manera se evita que la bomba esté prendiendo y apagando si es que se utiliza solo el sensor alto para encender y apagar la bomba. Un caso parecido será el de la cisterna; la cisterna solo enviará agua al tinaco si ésta se encuentra llena o si tiene un nivel medio de agua (por el hecho de estar mandando el líquido al tinaco) y en caso de estar vacía o aunque el nivel bajo esté detectando agua no prenderá la bomba hasta que el nivel alto detecte que ya está llena de nuevo, ésto para evitar (al igual que en el caso del tinaco) que con el simple cambio de un solo sensor esté prendiendo y apagando la bomba; es aquí donde se aplica la lógica y es el trabajo que hace en éste proyecto la tarjeta de freescale.

Hello Freedom users I have created another full board review this time for the FRDM-KL05Z always including clear instructions to program and debug your first project. I'm still working on the video version (looking for a better accent :smileyconfused:), but the commands illustrated by screen captures should be easy to follow. Freescale Freedom development platform: [FRDM-K... | element14 Enjoy Greg