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This post explains the implementation to operate the KW36 MCU on VLPR when the clocking mode is BLPE or BLPI. It's also included the explanation on how to configure clocks for BLPE and BLPI modes. For this example, the beacon demo from the wireless examples of the FRDM-KW36 is used. FRDM-KW36 SDK can be downloaded from MCUXpresso webpage. A recommended option to configure clock modes is "Config Tools" from MCUXpresso. Config Tools is embedded to MCUXpresso IDE, or you can download Config Tools from this LINK if you are using other supported IDE for this tool. MCUXpresso IDE is used in this example. Configure BLPE or BLPI clocking modes Select your proyect on MCUXpresso IDE, then open the clocks configuration window from Config Tools by clicking the arrow next to Config Tools icon from your MCUXpresso IDE, and then select "Open Clocks" as shown in Figure 1. Figure 1. Open Clocks from Config Tools using MCUXpresso IDE. A clocks diagram window will be opened. To configure the clock modes just select your option "BLPI" or "BLPE" on MCG Mode as shown in Figure 2. Clock will be automatically configured. Figure 2. MCG Mode selection. Now let's configure the appropiate clocks for Core clock and Bus clock to run in VLPR. Figure 3 taken from KW36 Reference Manual shows achievables frequencies when MCU is on VLPR.  Figure 3. VLPR clocks. Core clock should be 4MHz for BLPE and BLPI clocking modes, and Bus clock should be 1MHz for BLPE and 800kHz for BLPI.  Figure 4 shows clocks distribution for BLPE and Figure 5 for BLPI to operate with discussed frequencies. Figure 4. Clock distribution - VLPR and BLPE. Figure 5. Clock distribution - VLPR and BLPI. Press "Update Project" (Figure 6) to apply your new clock configuration to your firmware, then change perspective to "Develop" icon on right corner up to go to your project (See Figure 7). Compile your project to apply the changes. Figure 6. Update Project button. Figure 7. Develop button. At this point your project is ready to work with BLPE or BLPI clocks modes. Now, let's configure MCU to go to VLPR power mode. Configure VLPR mode VLPR mode can be configured using Config Tools too, but you may have an error trying to configure it when BLPE mode, this is because CLKDIV1 register cannot be written when the device is on VLPR mode. For this example, let's configure MCU into VLPR mode by firmware. Follow next steps to configure KW36 into VLPR power mode: 1. Configure RF Ref Oscillator to operate in VLPR mode. By default, the RF Ref Osc it's configured to operate into RUN mode. To change it to operate on VLPR mode just change the bits RF_OSC_EN from Radio System Control from 1 (RUN) to 7 (VLPR). Figure 8 taken from KW36 Reference Manual shows RF_OSC_EN value options from Radio System Control.    Figure 8. RF_OSC_EN bits from Radio System Control register. Go to clock_config.c file in your MCUXpresso project and search for "BOARD_RfOscInit" function. Change the code line as shown in Figure 9 to configure RF Ref Osc to work into VLPR mode. You may see a window asking if you want to make writable the read-only file, click Yes. Figure 9. Code line to configure RF Ref Osc to work into VLPR mode Be aware that code line shown in Figure 9 may change with updates done in clocks using Config Tools. Note 2. Configure DCDC in continuous mode. According to KW36 Reference Manual, the use of BLPE in VLPR mode is only feasible when the DCDC is configured for continuous mode. First, let's define gDCDC_Enabled_d flag to 1 on preprocesor. With this implementation, the use of DCDC_Init function will be enabled, and it's where we going to add the code line to enable continuous mode. Right click on your project, select Properties, go to Settings under C/C++ Build, then Preprocessor under MCU C Compiler (Figure 10).   Figure 10. MCUXpresso Preprocessor   Click on add button from Defined symbols, write gDCDC_Enabled_d=1 and click OK to finish (Figure 11).  Re-compile your project. Figure 11. MCUXpresso Defined symbols   Now let's set VLPR_VLPW_CONFIG_DCDC_HP bits to 1 from DCDC_REG0 register. Figure 12 was taken from KW36 Reference Manual. Figure 12. VLPR_VLPW_CONFIG_DCDC_HP values. Go to DCDC_Init  function and add the next code line to enable continuous mode on DCDC: DCDC->REG0 |= DCDC_REG0_VLPR_VLPW_CONFIG_DCDC_HP_MASK; Figure 13 shows the previous code line implemented in firmware project inside of DCDC_Init function. Figure 13. Continuous mode for DCDC enabled. 3. Configure MCU into VLPR mode To finish, let's write the code to configure MCU into VLPR power mode. Copy and paste next code just after doing implementation described on step 1 and 2: #if (defined(FSL_FEATURE_SMC_HAS_LPWUI) && FSL_FEATURE_SMC_HAS_LPWUI) SMC_SetPowerModeVlpr(SMC, false); #else SMC_SetPowerModeVlpr(SMC); #endif while (kSMC_PowerStateVlpr != SMC_GetPowerModeState(SMC)) { } It may be needed to add the SMC library: #include "fsl_smc.h" The code is configuring MCU into VLPR mode with bits RUNM from SMC_PMCTRL register (Figure 14) and then check if it was correctly configured by reading status bits PMSTAT from SMC_PMSTAT register (Figure 15) Figure 14. RUNM bits from SMC_PMCTRL register. Figure 15. PMSTAT bits from  SMC_PMSTAT register. KW36 is ready to operate and BLPE or BLPI clocking modes with VLPR power mode.
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Introduction In some applications, is it necessary to keep updated the software running in many MCU's that take part in the system, fortunately, Over The Air Programming, it's a custom Bluetooth LE service developed to send "over the air" software updates for the KW MCU series. FRDM-KW36 SDK already provides the "otap_client" software, that can be used together with the "otap_bootloader" such as it is described in the following community post: Reprogramming a KW36 device using the OTAP Client Software to reprogram the KW36. This example can be modified to store code for another MCU and later send the software update to this device as depicted in the figure below. This post guides you on modifying the OTAP client software to support software updates for other MCU's. Preparing the OTAP client software The starting point of the following modifications is supposing that there is no need to perform over the air updates for the KW36 MCU, so the use of the "otap_bootloader" is obsolete and will be removed in this example. In other words, KW36 will be programmed only with the "otap_client" code. Open the MCUXpresso settings window (Project->Properties->"C/C++ Build->MCU settings") and configure the following fields. Save the changes. For external storage: For internal storage: Locate the "app_preinclude.h" file, and set the storage method, as follows: For external storage: #define gEepromType_d       gEepromDevice_AT45DB041E_c For internal storage: #define gEepromType_d        gEepromDevice_InternalFlash_c Locate the "main_text_section.ldt" linker script into the "linkscripts" folder, and delete it from the project.  Search in the project for "OTA_SetNewImageFlag();" and "ResetMCU();" functions in the "otap_client.c" file (source->common->otap_client->otap_client.c) and delete or comment. (For reference, there are 4 in total). Locate the following code in "OtaSupport.h" (framework->OtaSupport->Interface) and delete or comment. extern uint16_t gBootFlagsSectorBitNo;‍‍‍‍‍‍ void OTA_SetNewImageFlag(void);‍‍‍‍‍‍‍ Locate the following code in "OtaSupport.c" (framework->OtaSupport->Source) and delete or comment. extern uint32_t __BootFlags_Start__[]; #define gBootImageFlagsAddress_c ((uint32_t)__BootFlags_Start__)‍‍‍‍‍‍‍‍‍‍‍‍ #if !gEnableOTAServer_d || (gEnableOTAServer_d && gUpgradeImageOnCurrentDevice_d) /*! Variables used by the Bootloader */ #if defined(__IAR_SYSTEMS_ICC__) #pragma location = "BootloaderFlags" const bootInfo_t gBootFlags = #elif defined(__GNUC__) const bootInfo_t gBootFlags __attribute__ ((section(".BootloaderFlags"))) = #elif defined(__CC_ARM) volatile const bootInfo_t gBootFlags __attribute__ ((section(".BootloaderFlags"))) = #else #error "Compiler unknown!" #endif { {gBootFlagUnprogrammed_c}, {gBootValueForTRUE_c}, {0x00, 0x02}, {gBootFlagUnprogrammed_c}, #if defined(CPU_K32W032S1M2VPJ_cm4) && (CPU_K32W032S1M2VPJ_cm4 == 1) {PLACEHOLDER_SBKEK}, {BOOT_MAGIC_WORD} #endif }; #endif /* !gEnableOTAServer_d || (gEnableOTAServer_d && gUpgradeImageOnCurrentDevice_d) */‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍ uint16_t gBootFlagsSectorBitNo; gBootFlagsSectorBitNo = gBootImageFlagsAddress_c/(uint32_t)((uint8_t*)FSL_FEATURE_FLASH_PFLASH_BLOCK_SECTOR_SIZE);‍‍‍‍ gBootFlagsSectorBitNo = gBootImageFlagsAddress_c/(uint32_t)((uint8_t*)FSL_FEATURE_FLASH_PAGE_SIZE_BYTES);‍‍‍‍ void OTA_SetNewImageFlag(void) { #if (gEepromType_d != gEepromDevice_None_c) && (!gEnableOTAServer_d || (gEnableOTAServer_d && gUpgradeImageOnCurrentDevice_d)) /* OTA image successfully written into the non-volatile storage. Set the boot flag to trigger the Bootloader at the next CPU Reset. */ union{ uint32_t value; uint8_t aValue[FSL_FEATURE_FLASH_PFLASH_BLOCK_WRITE_UNIT_SIZE]; }bootFlag; #if defined(CPU_K32W032S1M2VPJ_cm4) && (CPU_K32W032S1M2VPJ_cm4 == 1) uint8_t defaultSBKEK[SBKEK_SIZE] = {DEFAULT_DEMO_SBKEK}; #endif uint32_t status; if( mNewImageReady ) { NV_Init(); bootFlag.value = gBootValueForTRUE_c; status = NV_FlashProgramUnaligned((uint32_t)&gBootFlags.newBootImageAvailable, sizeof(bootFlag), bootFlag.aValue); if( (status == kStatus_FLASH_Success) && FLib_MemCmpToVal(gBootFlags.internalStorageAddr, 0xFF, sizeof(gBootFlags.internalStorageAddr)) ) { bootFlag.value = gEepromParams_StartOffset_c + gBootData_ImageLength_Offset_c; status = NV_FlashProgramUnaligned((uint32_t)&gBootFlags.internalStorageAddr, sizeof(bootFlag), bootFlag.aValue); } #if defined(CPU_K32W032S1M2VPJ_cm4) && (CPU_K32W032S1M2VPJ_cm4 == 1) if( status == kStatus_FLASH_Success ) { /* Write the default SBKEK for secured OTA */ status = NV_FlashProgramUnaligned((uint32_t)&gBootFlags.sbkek, SBKEK_SIZE, defaultSBKEK); } #endif if( status == kStatus_FLASH_Success ) { mNewImageReady = FALSE; } } #endif }‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍‍   At this point, the FRDM-KW36 can receive and store any image for any MCU and can request a further software update from the OTAP server device.    Adding API's to reprogram the "MCU X" on OTAP client software Once the software update has been downloaded from the OTAP Server into the OTAP Client, the developer should request the software update from the OTAP Client to the "MCU X" through a serial protocol such as UART, SPI, CAN, etc. You should develop the API's and the protocol according to the requirements for your system to send the software update to the "MCU X" (as well as the bootloader for the MCU X). The handling your protocol can be integrated into the OTAP client code replacing "ResetMCU()" (The same code removed in step 4) in the code by "APISendSoftwareUpdateToMCUX()" for instance, since at this point the image was successfully sent over the air and stored in the memory of the KW36. 
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The connectivity software is an add-on of the Kinetis SDK, therefore the demos are referenced to a KSDK path variable named "KSDK_PATH" in IAR. The KSDK_PATH variable contains the path of the installation folder for the KSDK version in your PC. Taking as an example the MRB-KW01 SMAC Connectivity Software, we can realize that this variable is used to reference for libraries. In particular, this SMAC software for the MRB-KW01 works with KSDK 1.2, that is why you could have troubles if the variable is referenced to another KSDK version (for example KSDK 1.1). Follow the next steps to modify the KSDK_PATH variable in your computer: 1. Right click on "computer", then click "properties" 2. A Control Panel window will be opened. Click on "Advanced system settings" 3. A system Properties windows will be opened. Select the "Advanced" tab, then click "Environment Variables". 4. Select the KSDK_PATH variable and assure that it stores the correct path needed for your project. In case that you need to modify the variable, then click "Edit" 5. Finally click "Ok" to close all tabs and you will be able to run your connectivity software without problems. Best regards, Luis Burgos.
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This article introduces the Wi-Fi automatic recovery feature as well as how to enable and verify it on RW61x SDK. 1. Introduction Wi-Fi automatic recovery is a NXP proprietary feature that monitors Wi-Fi running status and recovers Wi-Fi out of exception state when running into one of the following cases: Driver fails to wakeup Wi-Fi MCU for commands/Tx Driver fails to receive command response from Wi-Fi MCU Driver detects Wi-Fi firmware is in abnormal state Once Wi-Fi automatic recovery is triggered, Wi-Fi middleware and driver will clean up the running states, reset Wi-Fi MCU power, reload Wi-Fi firmware and restart Wi-Fi initialization. It will not impact the ongoing Bluetooth LE/802.15.4 activities. Figure 1 is the Wi-Fi software architecture. Figure 1: Wi-Fi Software Architecture Figure 2 shows the work flow of Wi-Fi automatic recovery: Figure 2: Wi-Fi Automatic Recovery Work Flow Wi-Fi driver detects command timeout/wakeup card timeout/FW exception   Wi-Fi driver triggers WLAN reset to Stop Wi-Fi activities and de-initialize Wi-Fi Reset Wi-Fi power Reload the Wi-Fi only firmware and wait for the firmware to be active Send an event to notify the application before resetting it   2. SDK Configuration The Wi-Fi automatic recovery feature is not enabled by default in RW61x SDK. It needs to be enabled explicitly: Add below line in <example>/source/wifi_config.h to enable the feature  #define CONFIG_WIFI_RECOVERY 1 Besides, please also make sure the "CONFIG_WIFI_RESET" macro is defined as "1" in the SDK.   3. Automatic Recovery Verification This section introduces how to verify the Wi-Fi automatic recovery feature on RW61x SDK. wifi_cli application is used as example here together with the RW612 RD board. Refer to UM11799: NXP Wi-Fi and Bluetooth Demo Applications for RW61x for steps to flash and run Wi-Fi applications. Below are the steps to verify the Wi-Fi automatic recovery feature: Step 1: Define CONFIG_WIFI_RECOVERY in wifi_cli/source/wifi_config.h     #define CONFIG_WIFI_RECOVERY 1 Step 2: Build and flash the wifi_cli application onto RW612 RD board Step 3: Connect RW612 RD board to a serial terminal Step 4: Reset the power of RW612 RD board Step 5: Trigger Wi-Fi MCU into hung-up state with the following command to mimic a command timeout     # wlan-recovery-test Step 6: Wi-Fi recovery background task detects Wi-Fi FW hang and starts recovery process [wifi] Warn: Command response timed out. command 0x8b, len 12, seqno 0x1c timeout happends. # app_cb: WLAN: FW hang Event: 14 --- Disable WiFi --- [wifi] Warn: Recovery in progress. command 0x10 skipped [wifi] Warn: Recovery in progress. command 0x10 skipped [wifi] Warn: Recovery in progress. command 0xaa skipped [dhcp] Warn: server not dhcpd_running. --- Enable WiFi --- Initialize WLAN Driver [wifi] Warn: WiFi recovery mode done! Wi-Fi cau temperature : 31 STA MAC Address: C0:95:DA:01:1D:A6 board_type: 2, board_type mapping: 0----QFN 1----CSP 2----BGA app_cb: WLAN initialized ======================================== WLAN CLIs are initialized ======================================== ENHANCED WLAN CLIs are initialized ======================================== HOST SLEEP CLIs are initialized ======================================== CLIs Available: ======================================== help clear wlan-version wlan-mac wlan-thread-info wlan-net-stats wlan-set-mac <MAC_Address> wlan-scan wlan-scan-opt ssid <ssid> bssid ... wlan-add <profile_name> ssid <ssid> bssid... wlan-remove <profile_name> wlan-list wlan-connect <profile_name> wlan-connect-opt <profile_name> ... wlan-reassociate wlan-start-network <profile_name> wlan-stop-network wlan-disconnect wlan-stat wlan-info wlan-address wlan-uap-disconnect-sta <mac address> wlan-get-uap-channel wlan-get-uap-sta-list wlan-ieee-ps <0/1> wlan-set-ps-cfg <null_pkt_interval> wlan-deep-sleep-ps <0/1> wlan-get-beacon-interval wlan-get-ps-cfg wlan-set-max-clients-count <max clients count> wlan-get-max-clients-count wlan-rts <sta/uap> <rts threshold> wlan-frag <sta/uap> <fragment threshold> wlan-host-11k-enable <0/1> wlan-host-11k-neighbor-req [ssid <ssid>] wlan-host-11v-bss-trans-query <0..16> wlan-mbo-enable <0/1> wlan-mbo-nonprefer-ch <ch0> <Preference0: 0/1/255> <ch1> <Preference1: 0/1/255> wlan-get-log <sta/uap> <ext> wlan-roaming <0/1> <rssi_threshold> wlan-multi-mef <ping/arp/multicast/del> [<action>] wlan-wakeup-condition <mef/wowlan wake_up_conds> wlan-auto-host-sleep <enable> <mode> <rtc_timer> <periodic> wlan-send-hostcmd wlan-ext-coex-uwb wlan-set-uap-hidden-ssid <0/1/2> wlan-eu-crypto-rc4 <EncDec> wlan-eu-crypto-aes-wrap <EncDec> wlan-eu-crypto-aes-ecb <EncDec> wlan-eu-crypto-ccmp-128 <EncDec> wlan-eu-crypto-ccmp-256 <EncDec> wlan-eu-crypto-gcmp-128 <EncDec> wlan-eu-crypto-gcmp-256 <EncDec> wlan-set-antcfg <ant_mode> <evaluate_time> <evaluate_mode> wlan-get-antcfg wlan-scan-channel-gap <channel_gap_value> wlan-wmm-stat <bss_type> wlan-reset wlan-set-regioncode <region-code> wlan-get-regioncode wlan-11d-enable <sta/uap> <0/1> wlan-uap-set-ecsa-cfg <block_tx> <oper_class> <new_channel> <switch_count> <bandwidth> wlan-csi-cfg wlan-set-csi-param-header <sta/uap> <csi_enable> <head_id> <tail_id> <chip_id> <band_config> <channel> <csi_monitor_enable> <ra4us> wlan-set-csi-filter <opt> <macaddr> <pkt_type> <type> <flag> wlan-txrx-histogram <action> <enable> wlan-subscribe-event <action> <type> <value> <freq> wlan-reg-access <type> <offset> [value] wlan-uapsd-enable <uapsd_enable> wlan-uapsd-qosinfo <qos_info> wlan-uapsd-sleep-period <sleep_period> wlan-tx-ampdu-prot-mode <mode> wlan-rssi-low-threshold <threshold_value> wlan-rx-abort-cfg wlan-set-rx-abort-cfg-ext enable <enable> margin <margin> ceil <ceil_thresh> floor <floor_thresh> wlan-get-rx-abort-cfg-ext wlan-cck-desense-cfg wlan-net-monitor-cfg wlan-set-monitor-filter <opt> <macaddr> wlan-set-monitor-param <action> <monitor_activity> <filter_flags> <radio_type> <chan_number> wlan-set-tsp-cfg <enable> <backoff> <highThreshold> <lowThreshold> <dutycycstep> <dutycycmin> <highthrtemp> <lowthrtemp> wlan-get-tsp-cfg wlan-get-signal wlan-set-bandcfg wlan-get-bandcfg wlan-set-ips <option> wlan-enable-disable-htc <option> wlan-set-su <0/1> wlan-set-forceRTS <0/1> wlan-set-mmsf <enable> <Density> <MMSF> wlan-get-mmsf wlan-set-multiple-dtim <value> wlan-set-country <country_code_str> wlan-set-country-ie-ignore <0/1> wlan-single-ant-duty-cycle <enable/disable> [<Ieee154Duration> <TotalDuration>] wlan-dual-ant-duty-cycle <enable/disable> [<Ieee154Duration> <TotalDuration> <Ieee154FarRangeDuration>] wlan-external-coex-pta enable <PTA/WCI-2/WCI-2 GPIO> ExtWifiBtArb <enable/disable> PolGrantPin <high/low> PriPtaInt <enable/disable> StateFromPta <state pin/ priority pin/ state input disable> SampTiming <Sample timing> InfoSampTiming <Sample timing> TrafficPrio <enable/disable> CoexHwIntWic <enable/disable> wlan-sta-inactivityto <n> <m> <l> [k] [j] wlan-get-temperature wlan-auto-null-tx <sta/uap> <start/stop> wlan-detect-ant <detect_mode> <ant_port_count> channel <channel> ... wlan-recovery-test wlan-get-channel-load <set/get> <duration> wlan-get-txpwrlimit <subband> wlan-set-chanlist wlan-get-chanlist wlan-set-txratecfg <sta/uap> <format> <index> <nss> <rate_setting> <autoTx_set> wlan-get-txratecfg <sta/uap> wlan-get-data-rate <sta/uap> wlan-get-pmfcfg wlan-uap-get-pmfcfg wlan-set-ed-mac-mode <interface> <ed_ctrl_2g> <ed_offset_2g> <ed_ctrl_5g> <ed_offset_5g> wlan-get-ed-mac-mode <interface> wlan-set-tx-omi <interface> <tx-omi> <tx-option> <num_data_pkts> wlan-set-toltime <value> wlan-set-rutxpwrlimit wlan-11ax-cfg <11ax_cfg> wlan-11ax-bcast-twt <dump/set/done> [<param_id> <param_data>] wlan-11ax-twt-setup <dump/set/done> [<param_id> <param_data>] wlan-11ax-twt-teardown <dump/set/done> [<param_id> <param_data>] wlan-11ax-twt-report wlan-get-tsfinfo <format-type> wlan-set-clocksync <mode> <role> <gpio_pin> <gpio_level> <pulse width> wlan-suspend <power mode> ping [-s <packet_size>] [-c <packet_count>] [-W <timeout in sec>] <ipv4/ipv6 address> iperf [-s|-c <host>|-a|-h] [options] dhcp-stat ======================================== --- Done --- Step 7: Run other Wi-Fi shell commands to confirm Wi-Fi resumes to normal state  
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Matter is the industry-unifying standard from the Connectivity Standards Alliance that is delivering reliable, secure and interoperable connectivity for smart home devices, ensuring that they will work seamlessly together, today and tomorrow. From connectivity to security, processing and software, NXP offers complete end-to-end solutions for accelerating the development of Matter-enabled devices and is focused on helping our customers overcome the complexity and challenges that come with developing around this game-changing technology.   Getting Started Our investment in Matter starts with easing the development experience for adopting Matter in existing or new designs. With the breadth and scale of our portfolios, we scale to the system level to enable the autonomous edge - bringing intelligence to the edge. This approach provides developers with integrated platforms for the processing, connectivity and security requirements to go from prototype to production faster.   Matter Open-Source Protocol Compatible Products    Matter (previously known as Project CHIP) is a single, unified, application-layer connectivity standard designed to enable developers to connect and build reliable, secure IoT ecosystems and increase compatibility among Smart Home and Building devices. Backed by major brands and developed through collaboration within the Connectivity Standards Alliance (previously known as the Zigbee Alliance), Matter is an open-source royalty-free connectivity standard built with market-proven technologies using Internet Protocol (IP) and compatible with Thread and Wi-Fi network transports.   Useful Links   Getting Started with MCUXpresso for VS Code: Matter on Windows (24.12.71) MCUXpresso extension for VS Code v24.12.71 integrates the Matter toolchain for development on Windows, macOS and Linux.    Understanding Matter Terminology   Matter Is What's Cooking and NXP Has All the Right Ingredients     Matter GitHub Links    Releases Matter 
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Board pictures (KW47-M2) Connectors (KW47-M2) Part Identifier Connector Type Description J3 2x5 pin header SWD DNP J8 1x6 pin header UART1 – FTDI DNP J9 1x6 pin header Power connector DNP Jumpers (KW47-M2) Part Identifier Connector Type Description JP5 2x3 pin header supply power source selection jumper: 1-2 shorted (default configuration): Use this configuration to set target MCU in DCDC mode.  3-4 shorted: Use this configuration to set target MCU in LDO/Bypass mode. All MCU power domains are supplied by P3V3_DUT.  JP4 1x2 pin header Target MCU boot configuration enable jumper: • Open (default setting): ISP mode is disabled • Shorted: ISP mode is enabled Push Buttons (KW47-M2) Part Identifier Switch name Description SW1 Reset button Resets the target MCU. This causes peripherals to reset to their default state. After this, MCU ROM bootloader will be executed. LED D1 turns on at SW1 press. SW2 User PB General purpose input. This pin supports low-power wakeup capabilities through Wake-Up Unit (WUU). LEDs (KW47-M2) Part Identifier Switch name Description D1 Reset LED Indicates a system reset event. When reset is triggered—such as by pressing the SW1 reset button—the D1 LED turns ON. D2 Led Green User indicator, indicates system activity   Power Configurations (KW47-M2) Populate J9 PWR connector. To run KW47 M2 as standalone, supply 3.3V to P3V3_DUT power rail Figure 1 J9 M10 Configuration (KW47-M2)   To get the KW47 M2 up and running, you need to select a power configuration through JP5 jumper. For more information on KW47 power configurations, refer to RM: Part Identifier pin Description JP5 1-2 1-2 shorted (default setting): Sets target MCU to DCDC mode. This mode is the recommended configuration. JP5 3-4 3-4 shorted: Sets target MCU to LDO mode.     External power configuration (KW47-M2) Enable KW47-M2 by supplying power through J9 connector: Note: When using DCDC or LDO mode, it is recommended to supply P3V3_DUT power rail only. Part Identifier pin Description J9 5 Use this pin to supply P3V3_DUT power rail with 3.3V. To get KW47-M2 up and running, it is recommended to set KW47 to DCDC mode and supply P3V3_DUT only. J9 3 Use this pin to supply P1V8_LDO power rail with 1.8V. This power rail is intended for an accurate control of VDD_RF power domain, but it is not necessary. J9 1 Use this pin to supply P1V1_EXT power rail with 1.1V. This power rail is intended for an accurate control of VDD_CORE power domain, but it is not necessary.     Programming the NBU in the KW47-M2 board The following steps guide you to program the NBU software for the KW47-M2 Place a jumper on the JP4 header while holding down the reset button (SW) on the module board. Then, connect the USB cable to the J8 connector (USB-to-serial bridge) and plug it into your computer. After the USB cable is connected, release the reset button.   Verify what COM Port was assigned to your KW47-M2 board. You can check the COM Port assigned in the Windows “Device Manager” program. Search for “Ports (COM & LPT)” and save the COM Port number. In this example the COM Port assigned was “COM19”   Navigate to your computer to the MCU-Link installation folder. The default installation path is located at “C:\nxp\LinkServer_25.3.31\MCU-LINK_installer Locate the “bin” folder and open it. Run the script “blhost” within a windows command prompt.   Type “blhost.exe -p COMX write-memory 0x48800000”, drag and drop the NBU binary file. When the process is ready you will see the response status "success"  
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[中文翻译版] 见附件   原文链接: https://community.nxp.com/docs/DOC-340993
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KW01 demo code for 315/434MHz application is ready. The demo code located in the "software Development Tools" FXTH87|Tire Pressure Monitor Sensor|Freescale
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Regarding to the "Reprogramming a KW36 device using the OTAP Client Software" and "Reprogramming a KW35 device using the OTAP Client Software" documents, there are some additional steps to debug the OTAP client software in the specific case when you use MCUXpresso together with a P&E micro debug probe. Just before to program the OTAP client project (the second software), the user must do the following: Open the "Debug Configurations" view clicking on the green bug as depicted below. Go to the "Debugger" perspective and search the "Advanced Options" button. Enable the "Preserve this range (Memory Range 0)" checkbox, and edit the textbox "From: 0" To: 1fff" for the KW36 device or "From: 0 To: 3fff" for the KW35 device. After to flash the device, disconnect and connect again. If everything it's OK, the RGB LED must blink (If you are using an FRDM board). Then, test the demo as described in the document.
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View the Webinar Recording
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By default, FRDM-KW36 board includes a 32MHz XTAL (YI) as shown in Figure 1 but there are cases where a 26MHz XTAL is needed instead of 32MHz XTAL for FRDM-KW36 or a custom KW36 board.   Figure 1. 32MHz XTAL from FRDM-KW36 schematics Wireless connectivity demos from FRDM-KW36 Sofware Development Kit are configured to run with a 32MHz XTAL by default, but it's very easy to modify the software to operate with a 26MHz XTAL. Follow next steps to configure a FRDM-KW36 wireless connectivity demo to operate with a 26MHz XTAL: 1. In clock_config.h file, change BOARD_XTAL0_CLK_HZ define from 32000000U to 26000000U as shown in Figure 2.   Figure 2. BOARD_XTAL0_CLK_HZ define in clock_config.h 2. Add RF_OSC_26MHZ=1 line in preprocessor: If using IAR IDE: Right click on your project, then click options (Figure 3). Figure 3. IAR project options Go to C/C++ Compiler tab, then Preprocessor, and add RF_OSC_26MHZ=1 line in defined symbols window (Figure 4). Figure 4. IAR Preprocessor If using MCUXpresso IDE: Right click on your project, select Properties, go to Settings under C/C++ Build, then Preprocessor under MCU C Compiler (Figure 5). Figure 5. MCUXpresso Preprocessor Click on add button from Defined symbols, write RF_OSC_26MHZ=1 and click OK to finish (Figure 6). Figure 6. MCUXpresso Defined symbols To finish, re-compile your project and it will be ready to operate with a 26MHz XTAL. FRDM-KW36 SDK can be downloaded from the MCUXpresso webpage.
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This video shows how to load the Open SDA software from PE micro to the TWR-KW2x in order to debug applications using USB port and without needing external JTAG debuggers. Required downloads: TWR-KW2x Board Support Package:Kinetis KW2x Tower System Modules|Freescale PE Micro - Open SDA: P&E Microcomputer Systems
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The customer wanted to update the FW of the PN7462 to an NFC cockpit. In general, we recommend that customers use MASS STORAGE MODE to update two files (including Flash and EEPROM) into memory. But there will always be customers who don’t know or how to successfully access MASS STORAGE MODE. They cannot succeed in doing so. Therefore, it is recommended to use the GUI FLASH tool to upgrade the FW to the NFC cabin. In order to clearly indicate the user how to use the GUI FLASH tool, this document describes this step by step.
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See the necessary steps to enable additional SDK components for a project when using GitHub SDK and Kconfig/CMake.
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[中文翻译版] 见附件   原文链接: https://community.nxp.com/docs/DOC-340508
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All FSCI packets contain a checksum field to verify data integrity. Every time a FSCI packet is created (by the Host or a Kinetis device) a new CRC is calculated based on every data byte in the FSCI frame. Compute CRC for TX packet The CRC field is calculated by XORing each byte contained in the FSCI command (opcode group, opcode, payload length and payload data). Checksum field then, accumulates the result of every XOR instruction.    In the firmware, the CRC is calculated in the 'FSCI_transmitPayload()' function wich is located in '<HSDK project>/framework/FSCI/Source/FsciCommunication.c' file. See FSCI_computeChecksum(). Example: TX: AspSetXtalTrim.Request 02 95 0A 01 30 AE    Sync            [1 byte] = 02    OpGroup     [1 byte] = 95    OpCode      [1 byte] = 0A    Length         [1 byte] = 01    trimValue     [1 byte] = 30    CRC            [1 byte] = AE     <------- (0x95) XOR (0A) XOR (0x01) XOR (0x30) = 0xAE Disable CRC field validation Every time a FSCI packet is received, the device verifies the checksum value.  The next changes will allow the board to receive FSCI packets without verifying the CRC field. However, the board will send the FSCI responses to the Host with this CRC field. Go to 'FsciCommunication.c' file. Search for 'fsci_packetStatus_t FSCI_checkPacket( clientPacket_t *pData, uint16_t bytes, uint8_t* pVIntf )' function. Comment all line codes related to checksum verifying. The image below shows what has to be commented. Compile project and load it to the board. Verify functionality with Test Tool. Select any command and check Raw Data checkbox. Delete the CRC data field and send the FSCI message pressing Send Raw. The loaded command set will vary depending on the demo you are using (Thread, ZigBee, BLE, etc.). The FSCI message is sent without a CRC field and the board responses to the command successfully.
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In this document we will be seeing how to create a BLE demo application for an adopted BLE profile based on another demo application with a different profile. In this demo, the Pulse Oximeter Profile will be implemented.  The PLX (Pulse Oximeter) Profile was adopted by the Bluetooth SIG on 14th of July 2015. You can download the adopted profile and services specifications on https://www.bluetooth.org/en-us/specification/adopted-specifications. The files that will be modified in this post are, app.c,  app_config.c, app_preinclude.h, gatt_db.h, pulse_oximeter_service.c and pulse_oximeter_interface.h. A profile can have many services, the specification for the PLX profile defines which services need to be instantiated. The following table shows the Sensor Service Requirements. Service Sensor Pulse Oximeter Service Mandatory Device Information Service Mandatory Current Time Service Optional Bond Management Service Optional Battery Service Optional Table 1. Sensor Service Requirements For this demo we will instantiate the PLX service, the Device Information Service and the Battery Service. Each service has a source file and an interface file, the device information and battery services are already implemented, so we will only need to create the pulse_oximeter_interface.h file and the pulse_oximeter_service.c file. The PLX Service also has some requirements, these can be seen in the PLX service specification. The characteristic requirements for this service are shown in the table below. Characteristic Name Requirement Mandatory Properties Security Permissions PLX Spot-check Measurement C1 Indicate None PLX Continuous Measurement C1 Notify None PLX Features Mandatory Read None Record Access Control Point C2 Indicate, Write None Table 2. Pulse Oximeter Service Characteristics C1: Mandatory to support at least one of these characteristics. C2: Mandatory if measurement storage is supported for Spot-check measurements. For this demo, all the characteristics will be supported. Create a folder for the pulse oximeter service in  \ConnSw\bluetooth\profiles named pulse_oximeter and create the pulse_oximeter_service.c file. Next, go to the interface folder in \ConnSw\bluetooth\profiles and create the pulse_oximeter_interface.h file. At this point these files will be blank, but as we advance in the document we will be adding the service implementation and the interface macros and declarations. Clonate a BLE project with the cloner tool. For this demo the heart rate sensor project was clonated. You can choose an RTOS between bare metal or FreeRTOS. You will need to change some workspace configuration.  In the bluetooth->profiles->interface group, remove the interface file for the heart rate service and add the interface file that we just created. Rename the group named heart_rate in the bluetooth->profiles group to pulse_oximeter and remove the heart rate service source file and add the pulse_oximeter_service.c source file. These changes will be saved on the actual workspace, so if you change your RTOS you need to reconfigure your workspace. To change the device name that will be advertised you have to change the advertising structure located in app_config.h. /* Scanning and Advertising Data */ static const uint8_t adData0[1] =  { (gapAdTypeFlags_t)(gLeGeneralDiscoverableMode_c | gBrEdrNotSupported_c) }; static const uint8_t adData1[2] = { UuidArray(gBleSig_PulseOximeterService_d)}; static const gapAdStructure_t advScanStruct[] = { { .length = NumberOfElements(adData0) + 1, .adType = gAdFlags_c, .aData = (void *)adData0 }, { .length = NumberOfElements(adData1) + 1, .adType = gAdIncomplete16bitServiceList_c, .aData = (void *)adData1 }, { .adType = gAdShortenedLocalName_c, .length = 8, .aData = "FSL_PLX" } }; We also need to change the address of the device so we do not have conflicts with another device with the same address. The definition for the address is located in app_preinclude.h and is called BD_ADDR. In the demo it was changed to: #define BD_ADDR 0xBE,0x00,0x00,0x9F,0x04,0x00 Add the definitions in ble_sig_defines.h located in Bluetooth->host->interface for the UUID’s of the PLX service and its characteristics. /*! Pulse Oximeter Service UUID */ #define gBleSig_PulseOximeterService_d         0x1822 /*! PLX Spot-Check Measurement Characteristic UUID */ #define gBleSig_PLXSpotCheckMeasurement_d      0x2A5E /*! PLX Continuous Measurement Characteristic UUID */ #define gBleSig_PLXContinuousMeasurement_d     0x2A5F /*! PLX Features Characteristic UUID */ #define gBleSig_PLXFeatures_d                  0x2A60 /*! Record Access Control Point Characteristic UUID */ #define gBleSig_RecordAccessControlPoint_d     0x2A52 We need to create the GATT database for the pulse oximeter service. The requirements for the service can be found in the PLX Service specification. The database is created at compile time and is defined in the gatt_db.h.  Each characteristic can have certain properties such as read, write, notify, indicate, etc. We will modify the existing database according to our needs. The database for the pulse oximeter service should look something like this. PRIMARY_SERVICE(service_pulse_oximeter, gBleSig_PulseOximeterService_d)     CHARACTERISTIC(char_plx_spotcheck_measurement, gBleSig_PLXSpotCheckMeasurement_d, (gGattCharPropIndicate_c))         VALUE_VARLEN(value_PLX_spotcheck_measurement, gBleSig_PLXSpotCheckMeasurement_d, (gPermissionNone_c), 19, 3, 0x00, 0x00, 0x00)         CCCD(cccd_PLX_spotcheck_measurement)     CHARACTERISTIC(char_plx_continuous_measurement, gBleSig_PLXContinuousMeasurement_d, (gGattCharPropNotify_c))         VALUE_VARLEN(value_PLX_continuous_measurement, gBleSig_PLXContinuousMeasurement_d, (gPermissionNone_c), 20, 3, 0x00, 0x00, 0x00)         CCCD(cccd_PLX_continuous_measurement)     CHARACTERISTIC(char_plx_features, gBleSig_PLXFeatures_d, (gGattCharPropRead_c))         VALUE_VARLEN(value_plx_features, gBleSig_PLXFeatures_d, (gPermissionFlagReadable_c), 7, 2, 0x00, 0x00)     CHARACTERISTIC(char_RACP, gBleSig_RecordAccessControlPoint_d, (gGattCharPropIndicate_c | gGattCharPropWrite_c))         VALUE_VARLEN(value_RACP, gBleSig_RecordAccessControlPoint_d, (gPermissionNone_c), 4, 3, 0x00, 0x00, 0x00)         CCCD(cccd_RACP) For more information on how to create a GATT database you can check the BLE Application Developer’s Guide chapter 7. Now we need to make the interface file that contains all the macros and declarations of the structures needed by the PLX service. Enumerated types need to be created for each of the flags field or status field of every characteristic of the service. For example, the PLX Spot-check measurement field has a flags field, so we declare an enumerated type that will help us keep the program organized and well structured. The enum should look something like this: /*! Pulse Oximeter Service - PLX Spotcheck Measurement Flags */ typedef enum {     gPlx_TimestampPresent_c                      = BIT0,     /* C1 */     gPlx_SpotcheckMeasurementStatusPresent_c     = BIT1,     /* C2 */     gPlx_SpotcheckDeviceAndSensorStatusPresent_c = BIT2,     /* C3 */     gPlx_SpotcheckPulseAmplitudeIndexPresent_c   = BIT3,     /* C4 */     gPlx_DeviceClockNotSet_c                     = BIT4 } plxSpotcheckMeasurementFlags_tag; The characteristics that will be indicated or notified need to have a structure type that contains all the fields that need to be transmitted to the client. Some characteristics will not always notify or indicate the same fields, this varies depending on the flags field and the requirements for each field. In order to notify a characteristic we need to check the flags in the measurement structure to know which fields need to be transmitted. The structure for the PLX Spot-check measurement should look something like this: /*! Pulse Oximeter Service - Spotcheck Measurement */ typedef struct plxSpotcheckMeasurement_tag {     ctsDateTime_t              timestamp;             /* C1 */     plxSpO2PR_t                SpO2PRSpotcheck;       /* M */     uint32_t                   deviceAndSensorStatus; /* C3 */     uint16_t                   measurementStatus;     /* C2 */     ieee11073_16BitFloat_t     pulseAmplitudeIndex;   /* C4 */     uint8_t                    flags;                 /* M */ }plxSpotcheckMeasurement_t; The service has a configuration structure that contains the service handle, the initial features of the PLX Features characteristic and a pointer to an allocated space in memory to store spot-check measurements. The interface will also declare some functions such as Start, Stop, Subscribe, Unsubscribe, Record Measurements and the control point handler. /*! Pulse Oximeter Service - Configuration */ typedef struct plxConfig_tag {     uint16_t      serviceHandle;     plxFeatures_t plxFeatureFlags;     plxUserData_t *pUserData;     bool_t        procInProgress; } plxConfig_t; The service source file implements the service specific functionality. For example, in the PLX service, there are functions to record the different types of measurements, store a spot-check measurement in the database, execute a procedure for the RACP characteristic, validate a RACP procedure, etc. It implements the functions declared in the interface and some static functions that are needed to perform service specific tasks. To initialize the service you use the start function. This function initializes some characteristic values. In the PLX profile, the Features characteristic is initialized and a timer is allocated to indicate the spot-check measurements periodically when the Report Stored Records procedure is written to the RACP characteristic. The subscribe and unsubscribe functions are used to update the device identification when a device is connected to the server or disconnected. bleResult_t Plx_Start (plxConfig_t *pServiceConfig) {         mReportTimerId = TMR_AllocateTimer();         return Plx_SetPLXFeatures(pServiceConfig->serviceHandle, pServiceConfig->plxFeatureFlags); } All of the services implementations follow a similar template, each service can have certain characteristics that need to implement its own custom functions. In the case of the PLX service, the Record Access Control Point characteristic will need many functions to provide the full functionality of this characteristic. It needs a control point handler, a function for each of the possible procedures, a function to validate the procedures, etc. When the application makes a measurement it must fill the corresponding structure and call a function that will write the attribute in the database with the correct fields and then send an indication or notification. This function is called RecordMeasurement and is similar between the majority of the services. It receives the measurement structure and depending on the flags of the measurement, it writes the attribute in the GATT database in the correct format. One way to update a characteristic is to create an array of the maximum length of the characteristic and check which fields need to be added and keep an index to know how many bytes will be written to the characteristic by using the function GattDb_WriteAttribute(handle, index, &charValue[0]). The following function shows an example of how a characteristic can be updated. In the demo the function contains more fields, but the logic is the same. static bleResult_t Plx_UpdatePLXContinuousMeasurementCharacteristic ( uint16_t handle, plxContinuousMeasurement_t *pMeasurement ) {     uint8_t charValue[20];     uint8_t index = 0;     /* Add flags */     charValue[0] = pMeasurement->flags;     index++;     /* Add SpO2PR-Normal */     FLib_MemCpy(&charValue[index], &pMeasurement->SpO2PRNormal, sizeof(plxSpO2PR_t));     index += sizeof(plxSpO2PR_t);         /* Add SpO2PR-Fast */     if (pMeasurement->flags & gPlx_SpO2PRFastPresent_c)     {       FLib_MemCpy(&charValue[index], &pMeasurement->SpO2PRFast, sizeof(plxSpO2PR_t));       index += sizeof(plxSpO2PR_t);     }        return GattDb_WriteAttribute(handle, index, &charValue[0]); } The app.c handles the application specific functionality. In the PLX demo it handles the timer callback to make a PLX continuous measurement every second. It handles the key presses and makes a spot-check measurement each time the SW3 pushbutton is pressed. The GATT server callback receives an event when an attribute is written, and in our application the RACP characteristic is the only one that can be written by the client. When this event occurs, we call the Control Point Handler function. This function makes sure the indications are properly configured and check if another procedure is in progress. Then it calls the Send Procedure Response function, this function validates the procedure and calls the Execute Procedure function. This function will call one of the 4 possible procedures. It can call Report Stored Records, Report Number of Stored Records, Abort Operation or Delete Stored Records. When the project is running, the 4 LEDs will blink indicating an idle state. To start advertising, press the SW4 button and the LED1 will start flashing. When the device has connected to a client the LED1 will stop flashing and turn on. To disconnect the device, hold the SW4 button for some seconds. The device will return to an advertising state. In this demo, the spot-check measurement is made when the SW3 is pressed, and the continuous measurement is made every second. The spot-check measurement can be stored by the application if the Measurement Storage for spot-check measurements is supported (bit 2 of Supported Features Field in the PLX Features characteristic). The RACP characteristic lets the client control the database of the spot-check measurements, you can request the existing records, delete them, request the number of stored records or abort a procedure. To test the demo you can download and install the nRF Master Control application by Nordic Semiconductor on an Android Smartphone that supports BLE. This app lets you discover the services in the sensor and interact with each characteristic. The application will parse known characteristics, but because the PLX profile is relatively new, these characteristics will not be parsed and the values will be displayed in a raw format. Figure 1. nRF Master Control app
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The RF parameters for KW01 can be changed by firmware using the KW01 connectivity software. Frequency band: The operational frequency band can be changed in app_preinclude.h file stored in Source folder. You can select the operational frequency band for your application only setting "1" to the desired band and "0" for the unused bands. In the same file also the default phy mode can be selected: Center frequency, channel spacing, number of channels, bit rate, frequency deviation, filter bandwidth, and other RF parameters: Most common RF parameters can be changed in declaration of "phyPibRFConstants" on PhyPib.c file. Search for your operational band and phy mode. For example for US ISM band in phy mode 1: Then change the desired parameters. If you want to change, for example, FDev: select "Fdev_25000", then go to declaration and change it from one of the predefined list of values: Regards, Luis Burgos.
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