This post entry aims at explaining the debugging process oriented to EMVCo Contactless certification of a device integrating NXP's PN5180. The structure is the following: PN5180 Antenna design considerations Before going into the debugging process for the EMVCo Contactless Analog tests we will see some important considerations for an antenna design and impedance tuning oriented for an EMVCo compliant device. Antenna tuning recommendations The first recommendation is that with the Dynamic Power Control feature the PN5180 allows us to perform symmetrical antenna tuning instead of the typical asymmetrical tuning. This symmetrical tuning provides us with a better transfer function, being able to drive more power to the antenna. The following figure shows the Smith Chart with the S11 parameter plot of a device using a symmetrical antenna tuning:   The only disadvantage of the symmetrical tuning is that we need a current limiter to avoid destroying the chip because of exceeding the chip’s limits. In the case we are documenting today, the PN5180 DPC feature is used to limit the supply voltage and therefore the transmitter current depending on the load detected by the chip. Regarding the EMC filter, the inductor should fit with the following condition to guarantee a good relation between the AGC and the ITVDD: Another consideration is about the resistor used in the reception branch. This resistor controls the receiver sensibility and as a starting point is recommended to use a value to obtain an AGC in free air of: Reader Mode only design: AGC value in free air around 600dec Full NFC design: AGC value in free air around 300dec Finally, EMV contactless transactions are performed at 106kbps which would allow us to work with a high Q factor of the overall system. This means that the power gain can be higher, but at the same time it might also lead to some issues because of the lower bandwidth. In light of this, we have to bear in mind, that if the Q factor is too high it may lead to problems in the waveform tests. PN5180 DPC calibration The Dynamic Power Control is a feature that uses the AGC value to establish different power configurations depending on the load applied to the antenna. As I mentioned before, the main goal is to protect the chip from a transmitter current level that might destroy it. The first step before calibrating the DPC is to check the correlation between the AGC value and the transmitter current or ITVDD when different loads are applied to the antenna. Basically, we will play with the distance between the load and the device to get several points with different AGC values. Based on those measurements, we can plot a graph like the following: Normally we would use a reference PICC and a metal plane or phone to check that the behavior is linear and with no big difference between those loads. Once we have checked the correlation we can proceed with the calibration process, which can be done very easily with the NFC Cockpit software. Here the important thing is to control the ITVDD and keep it always below the chip’s limit. As you can see in the figure below, without the DPC, this symmetrical tuning would lead to a voltage above the limit for positions close to the reader antenna. However, with DPC we can control that voltage at any moment. Another consideration is that we have to make sure that the DPC is calibrated to have maximum power when the reference PICC is far from the reader to avoid a lack of power in the tests at those positions. EMV L1 Analog Tests Debugging process We are going to divide this debugging process into 3 main phases which are the power tests in the first instance, followed by the waveform tests and the reception tests. The reason why we set this order is to first debug the tests that may require HW modifications which have a strong impact on the other tests. This way, for example, if you have passed all power and waveform tests, debugging the reception tests may not have an impact on the results obtained previously. Power tests Tests setup In order to debug the power tests, we will need just an oscilloscope and an EMVCo reference PICC. We will need to connect the outputs J9 and J1 of the EMVCo reference PICC to the oscilloscope and set the jumper J8 of the reference PICC in non-linear load mode. The J9 of the EMVCo reference PICC is the DC_OUT output that we will use to measure the power received by the antenna. The J1 is the LETI_COIL_OUT output and we will use it to capture the command in the oscilloscope. The overall setup is depicted in the figure below. Performing tests We have to use the trigger to capture the REQA command sent from the DTE when the reference PICC is in the position we want to test. This capture can be seen in the two figures below. The yellow channel is the LETI_COIL_OUT of the EMVCo reference PICC and the blue channel represents the DC_OUT obtained from the J1 connector. As said previously, we will use the DC_OUT to measure the voltage in the period of the signal where there is no modulation, like this part highlighted with the red squared. We have zoomed into the period to get the average value using the oscilloscope measurement features. We will use this same procedure to evaluate the power tests in all positions. Depending on the position tested, the specifications define and certain range where the voltage measured should be fitted. In this sense, the maximum voltage level is common for all planes, but the minimum voltage allowed will decrease for positions further from the terminal.  In order to identify the critical positions for the power tests, we have to identify two different scenarios, the first one with the positions that might not reach the minimum voltage established, and the positions that might exceed the maximum value. For the first scenario the critical positions are the outer positions of the plane z = 4cm and the plane z=3cm as the external positions for plane z= 3cm have a bigger radius. The other scenario is that where you can be exceeding the maximum level. This situation can happen in the central positions of the lower planes, like plane z=1 or z=0. Debugging hints In order to overcome possible issues, we will give some tips that can be used for your design. Regarding a case of lack of power, first, we have to make sure that the DPC is correctly calibrated, meaning that you are operating in gear 0 for the external positions of planes 3 and 4 and that gear 0 is operating with full power. If we have verified those two things and we still have issues, we would need to change the tuning of the antenna and reduce the target impedance. This is graphically represented in the following Smith Chart: By reducing the impedance we increase the current that the PN5180 is driving to the antenna so the voltage would increase. Is important to always verify that we are working within the recommended operating range of the chip and that we are not exceeding the transmitter current limit. In a worst-case scenario, if we cannot achieve the voltage with these HW changes we would need to evaluate changes in the hardware design, like adding a ferrite sheet or changing the antenna dimensions or position. On the other hand, if the problem comes because we are exceeding the maximum voltage allowed by the specifications we can easily solve it by reducing the power configuration of the gear used in that specific position. Waveform tests Test setup For the waveform group of tests, we will use a setup consisting of the EMVCo reference PICC along with an oscilloscope and a PC software to evaluate the signal obtained from the oscilloscope. In our case, we will use the Wave Checker software from CETECOM. We need to connect the output J9 of the EMVCo reference PICC to the oscilloscope and set the jumper J8 of the EMVCo reference PICC in the fixed load position. The oscilloscope needs to be connected to the PC or laptop, so the software is able to get the waveform and analyze the parameters needed. Type A tests The waveform group of tests for Type A consists of the following test cases: TA121: t1 TA122: Monotonic Decrease TA123: Ringing TA124: t2 TA125: t3 and t4 TA127: Monotonic Increase TA128: Overshoot Some of these test cases are directly related to the parameters defined for the specific modulation phase for Type A at 106 kbps. This modulation phase along with the respective parameters is depicted in the figure below. When the Wave Checker gets the oscilloscope capture, it automatically analyzes the signal, performing all the measurements and comparing them with the specifications limits. Debugging hints for Type A The PN5180 has a few registers and parameters to control the wave shape generated by the NFC chip and transmitted by the antenna. These are the most relevant ones: TX_CLK_MODE_RM (RF_CONTROL_TX_CLK register) Rise and Fall times (RF_CONTROL_TX register) TX_OVERSHOOT_CONFIG register From all the different test cases we will show how to debug the t3 and t4 test case as it is usually the most problematic. For this purpose, we will start from a certain configuration where the waveform tests show the following results, with a fail in the t3 and t4 test case. In order to tackle this problem, we will rely on the TAU_MOD_RISING parameter from the RF_CONTROL_TX register of the PN5180. In this case, as the timings are slightly above the maximum allowed in the specifications we will decrease the TAU_MOD_RISING 3 points and execute again the tests. The results after the modification show that all test are passing with a certain margin:   Another parameter that the PN5180 has and can be used for the waveform tests is the TX_CLK_MODE_RM parameter from the RF_CONTROL_TX_CLK register. Below you can see two graphs that clearly illustrate the effect of this parameter over the waveform.  As you can see from the two figures, by changing the default high impedance configuration of 001, to a low side pull configuration the waveform results in a smoother decay of the envelope. Type B tests For Type B waveform, the specifications define the following test cases:  TB121: Modulation Index TB122: Fall time TB123: Rise time TB124: Monotonic Increase TB125: Monotonic Decrease TB126: Overshoots TB127: Undershoots Again, these tests are based on the different parameters that can be identified for the modulation phase of the Type B commands: Debugging hints for Type B The register and parameters that the PN5180 includes to control the waveform for type B are: TX_RESIDUAL_CARRIER (RF_CONTROL_TX register) TX_CLK_MODE_RM (RF_CONTROL_TX_CLK register) TX_UNDERSHOOT_CONFIG register TX_OVERSHOOT_CONFIG register For Type B, we will study the modulation index test case, as it is the one that needs to be adjusted more often. In this case, we start from a situation where the device presents problems in the modulation index at 1 cm, with a value below the limit. In order to make corrections of the modulation index we will use the TX_RESIDUAL_CARRIER parameter from the RF_CONTROL_TX register. This parameter controls the amplitude of the residual carrier during the modulated phase. For the present problem, we will increase it by 4 points and rerun the test. As you can see in the picture below, the modulation index is within the specifications limits with margin.  Adaptative Waveform Control The PN5180 has another interesting feature called Adaptative Waveform Control that is used to set a different transmitter configuration depending on the gear and protocol used at any moment. This way we can easily debug by positions and use specific configurations for a certain group of positions without the need of rerunning all the tests for the rest of the positions. With the AWC feature we can control the: TAU_MOD_FALLING TAU_MOD_RISING TX_RESIDUAL CARRIER We can see in the table an example of an AWC configuration for Type B. Where we have changed the Residual Carrier from gear 2 onwards. As you can see, It is also configured with a change in the falling and rising times from Gear 1. As you can see this Adaptative Waveform Control feature along with the DPC represent a powerful tool to easily debug waveform tests without a change in the HW. Reception tests The reception tests purpose is to evaluate the ability of the device to identify and correctly demodulate the responses from the PICC when this response comes in the limits of the specifications for amplitude and polarity of the modulation.  Tests setup The tools and setup needed to debug the reception tests for EMVCo are depicted in the following figure: Oscilloscope to capture the signal received by the reference PICC. Arbitrary Waveform Generator to generate the response of the PICC. PC Software to control the AWG and load the EMVCo responses to the EMVCo reference PICC. For our case, we will use the Wave Player software from CETECOM. EMVCo reference PICC. This time, we will use the output J9 of the reference PICC to the oscilloscope to capture the command from the reader and trigger the injection of the response from the waveform generator to reference PICC, connected to J2. We should connect the waveform generator to the computer that has the Wave Player software installed to load the EMVCo responses. Performing tests As said previously, the reception tests aim at testing the ability of the device to correctly interpret the response when it is generated at the limit of the amplitude and polarity of the modulation. Considering the positive and negative polarity and the maximum and minimum amplitude of the modulation we have the following four test cases that are performed both for Type A and Type B: Tx131: Minimum positive modulation Tx133 - Maximum positive modulation Tx135 - Minimum negative modulation Tx137 - Maximum negative modulation To debug these tests with the PN5180 we will use: RX_GAIN (RF_CONTROL_RX register) RX_HPCF (RF_CONTROL_RX register) MIN_LEVEL (SIGPRO_RM_CONFIG register) MIN_LEVELP (SIGPRO_RM_CONFIG register) The procedure is basically to use the Waveplayer to set the amplitude and polarity of the response and check in the device is the response was correctly received and demodulated. Debugging hints To debug the reception we will test different configuration for the RX_GAIN and RX_HPCF parameters that control the reception filters, amplifier and ADC blocks from the receiver branch. These receiver blocks are pictured in the diagram below. Depending on the values used for the RX_GAIN and RX_HPCF parameters, the filter will be defined accordingly. The following table shows the filter characteristics in relation to those values: If we don’t find a correct value to pass the test at a certain position, we should modify the Rx resistor in order to increase or decrease the receiver sensibility. Adaptative Receiver Control In the same line as the Adaptative Waveform Control, the PN5180 includes the Adaptative Receiver Control that can be used to define different reception configurations depending on the gear and protocol used. With the ARC we can control all the registers involved in the reception and apply a correction to the preconfigured value depending on the gear used.  We can see an example of the Adaptative Receiver Control configuration in the following table, where we have defined a correction of -1 to the MIN_LEVEL and the HPCF parameters from gear 1. We can also see that the RX_GAIN parameter has a correction of +2 from gear 0. The ARC is very useful when we can't find a proper configuration for all positions and we need a different set of values depending on the positions tested. Rx Matrix tool Another interesting tool for debugging the reception tests is the Rx Matrix tool. This tool is used to launch and tests different receiver configuration in an automated way. The Rx Matrix tool is integrated into NXP's NFC Cockpit and you can control the Arbitrary Waveform Generator to set the amplitude of the modulation used for the tests. We can select which parameters we want to change and in which range we want them to be tested and the Rx Matrix will automatically run all the possible combinations in a sweep.   With the Rx Matrix tool, we can select the expected response and the number of iterations we want to try for every possible configuration. That way we can obtain a success ratio for the communication and easily identify the best configuration for the position tested. An example of the Rx Matrix is given in the figure below. We have fixed the RX_GAIN and RX_HPCF parameters and performed a sweep for the MinLevel, testing it from a value of 0 to 8. We have set the Rx Matrix to execute 50 iterations for every configuration, obtaining the success ratio results plotted below. As you can see the Rx Matrix along with a Waveform Generator is a powerful tool to find the optimum receiver configuration in a short time and in an effortless way. PN5180 Ecosystem The PN5180 comes with a complete and useful product support package including: The demokit, that can be used to get introduced to the product and check its features. The NFC Cockpit, that we have talked about during this article, and that represents a powerful tool to control the PN5180 with a very intuitive and useful interface. We srongly recommend that you integrate this tool in your final device as it may save you a lot of time during the debugging phase. A complete documentation including the updated product datasheet, or a set of application notes to guide you through all the designing process, from the antenna design guide to the DPC configuration or use of the Rx Matrix tool. Last but not least, the NFC Reader library which is the recommended software stack for NXP's NFC frontends and NFC controllers with customizable firmware. NFC Reader Library The NFC Reader Library comes with built-in MCU support, but it can also run on different MCU platforms, as well as non-NXP. The library has been built in such a way that you can adapt it and implement the required driver for your host platform. Other characteristics are: It is free of charge and you can download the latest release from NXP’s website. It is a complete API for developing NFC and MIFARE-based applications. Includes an HTML-based API documentation for all the components, which is generated from source-code annotations.  Finally, the release includes several examples and applications. Among the examples and applications included in the NFC Reader Library we can highlight two applications that are very useful for the preparation of the Device Test Environment required for the EMVCo certification:  The SimplifiedAPI_EMVCo for the digital testing The SimplifiedAPI_EMVCo_Analog for the Analog testing. You can control all the parameters involved in both applications using the phNxpNfcRdLib_Config.h configuration file. The identification and modification of these parameters should be very easy as the code is well documented, like you can see in the code chunk in the image: Further information You can find more information about NFC in: Our NFC everywhere portal: https://www.nxp.com/nfc You can ask your question in our technical community: https://community.nxp.com/community/identification-security/nfc You can look for design partners: https://nxp.surl.ms/NFC_AEC And you can check our recorded training: http://www.nxp.com/support/online-academy/nfc-webinars:NFC-WEBINARS Video recorded session

Overview   Digital dashboard market is growing, especially e-Scooter, E-bike demand are also growing. This solution will cover a wide range of uses for identification and vehicular applications. This solution is based on i.MX RT technology and our NFC portfolio products. Near Field Communication (NFC) is a fast, intuitive technology that lets you interact securely with the world around you with a simple touch. NFC wireless proximity technology is available in billions of smartphones, tablets, consumer and industrial electronics—with new devices arriving almost daily. Block Diagram Products Category MCU Product URL 1 i.MX RT1060 Crossover MCU with Arm® Cortex®-M7 core  Product Description 1 The i.MX RT1060 is the latest addition to the industry's first crossover MCU series and expands the i.MX RT series to three scalable families. Product URL 2 LPC551x/S1x: Baseline Arm® Cortex®-M33-based Microcontroller Family  Product Description 2 The LPC551x/S1x MCU family expands the world’s first general purpose Cortex-M33-based MCU series, offering significant advantages for developers, including pin-, software- and peripheral-compatibility.   Category Charger Product URL 1 MWCT1x23: 65W+ Wireless Power Transmitter Controller  Product Description 1 The NXP® MWCT1x23 65W+ Wireless Power Transmitter Controller IC provides high speed control loops, robust foreign object detection, over voltage and over current protection to enable safe and secure power delivery through non-magnetic materials such as air, glass, wood, and plastic. Product URL 2 MWPR1x24: 65W+ Wireless Power Receiver with Integrated Radio  Product Description 2 The NXP® MWPR1x24 65W+ Wireless Power Receiver Controller with Integrated Radio IC provides all receiver parameters monitoring, communication with transmitter, over voltage and over current protection to enable safe and secure power delivery through non-magnetic materials such as air, glass, wood, and plastic.   Category Wireless Product URL 1 88W8987: 2.4/5 GHz Dual-Band 1x1 Wi-Fi® 5 (802.11ac) + Bluetooth® 5 Solution  Product Description 1 The 88W8987 is a highly integrated Wi-Fi (2.4/5 GHz) and Bluetooth single-chip solution specifically designed to support the speed, reliability and quality requirements of Very High Throughput (VHT) products.   Category Secure Element Product URL EdgeLock™ SE050: Plug & Trust Secure Element Family – Enhanced IoT security with maximum flexibility  Product Description The EdgeLock SE050 product family of Plug & Trust devices offers enhanced Common Criteria EAL 6+ based security, for unprecedented protection against the latest attack scenarios.   Category NFC Product URL 1 PN5180: Full NFC Forum-compliant frontend IC  Product Description 1 The PN5180 is a high-performance full NFC Forum-compliant frontend IC for various contactless communication methods and protocols. Product URL 2 PN7462: NFC Cortex®-M0 all-in-one microcontroller with optional contact interface for access control  Product Description 2 The PN7462 family consists of 32-bit Arm® Cortex®-M0-based NFC microcontrollers offering high performance and low power consumption. Product URL 3 MIFARE® DESFire® EV3: High-Security IC for Contactless Smart City Services  Product Description 3 The features of the MIFARE DESFire EV3 IC reflect NXP’s continued commitment to secure, connected and convenient contactless Smart City services.   Category Peripherals Product URL 1 PCA9955BTW: 16-channel Fm+ I²C-bus 57 mA/20 V constant current LED driver  Product Description 1 The PCA9955B is an I2C-bus controlled 16-channel constant current LED driver optimized for dimming and blinking 57 mA Red/Green/Blue/Amber (RGBA) LEDs in amusement products. Product URL 2 TJA1041A: High-speed CAN transceiver with standby and sleep mode  Product Description 2 The TJA1041A provides an advanced interface between the protocol controller and the physical bus in a Controller Area Network (CAN) node. Product URL 3 PCA85073A: Automotive tiny Real-Time Clock/Calendar with alarm function and I2C-bus  Product Description 3 The PCA85073A is a CMOS1 Real-Time Clock (RTC) and calendar optimized for low power consumption.

  Overview NXP home appliance solutions make every day easier: through quality, cost-effective products above the performance bar in processing, efficiency, safety, and functionality. NXP's integrated solutions are powering the next wave of smart buildings with cloud-based voice assistance, intelligent automation, monitoring, and safety. From multichannel home theater surround systems to tiny cell phones, we cover virtually every system in the home, in the car, or on the move. The i.MX 8M Mini is NXP’s first embedded multicore applications processor built using advanced 14LPC FinFET process technology, providing more speed and improved power efficiency; he i.MX 8M Mini family may be used in any general purpose industrial and IoT application. This solution provides an all audio and voice low latency processing with with a significant system simplification via integration. Use Cases Discover multicore solutions for multimedia and display applications with high-performance and low-power capabilities that are scalable, safe, and secure. HMI solutions for intuitive experiences Power-saving motor control and power management Voice, vision and anomaly detection Immersiv3D™ audio solution Block Diagram Products Category MPU Product URL i.MX 8M Mini - Arm® Cortex®-A53, Cortex-M4, Audio, Voice, Video  Product Description The i.MX 8M Mini is NXP’s first embedded multicore applications processor built using advanced 14LPC FinFET process technology, providing more speed and improved power efficiency.   Category Power Management Product URL PCA9450: Power Manage IC (PMIC) for i.MX 8M Mini/Nano/Plus  Product Description The PCA9450 is a single chip Power Management IC (PMIC) specifically designed to support i.MX 8M family processor in both 1 cell Li-Ion and Li-polymer battery portable application and 5 V adapter nonportable applications.   Category LED Driver Product URL PCA9955BTW: 16-channel Fm+ I²C-bus 57 mA/20 V constant current LED driver  Product Description The PCA9955B is an I2C-bus controlled 16-channel constant current LED driver optimized for dimming and blinking 57 mA Red/Green/Blue/Amber (RGBA) LEDs in amusement products.   Category Analog Switch Product URL NX3L1G3157: Low-ohmic single-pole double-throw analog switch  Product Description The NX3L1G3157 is a low-ohmic single-pole double-throw analog switch suitable for use as an analog or digital 2:1 multiplexer/demultiplexer.   Category Audio Streaming Product URL NXH3670: Ultra-low Power, Low Latency Audio for Wireless Gaming Headphone  Product Description The NxH3670 constitutes a highly integrated, single-chip ultra-low-power 2.4 GHz wireless transceiver with embedded MCU (Integrated Arm® Cortex®-M0 processor), targeted at wireless audio streaming for gaming headphones, delivering low latency audio and ultra-low power consumption.   Category Wi-Fi Product URL 88W8987: 2.4/5 GHz Dual-Band 1x1 Wi-Fi® 5 (802.11ac) + Bluetooth® 5 Solution  Product Description The 88W8987 is a highly integrated WLAN (2.4/5 GHz) and Bluetooth single-chip solution, specifically designed to support the speed, reliability, and quality requirements of next generation Very High Throughput (VHT) products.   Category Audio Amplifiers Product URL TDF8597TH: I2C-Bus Controlled Dual Channel 43 W/2 Ω, Single Channel 85 W/1 Ω Class-D Power Amplifier with Full Diagnostics  Product Description The TDF8597 is a dual Bridge-Tied Load (BTL) car audio amplifier comprising an NDMOST-NDMOST output stage based on SOI BCDMOS technology.

Demo See how NXP integrates automotive and microcontroller technology to develop next-generation drones including high reliability, industrial quality, and additional security with drone-code compliant flight management unit running PX4. Video Features Electronic speed controllers with Field Oriented Control of BLDC (Brushless DC motors) TJA110 2-wire  Automotive Ethernet PHY Transceiver|NXP  SCM-i.MX6 Training https://register.gotowebinar.com/rt/9153317036356506113  Find our more at www.nxp.com/uav

NXP's secure over-the-air communication for automotive networks features embedded hardware crystallographic engine for the rapid decryption of received data.   Features   MPC5748G targets High-End Body and High-End gateway Rich communication peripheral set & HSM - embedded Security Module Encryption, decryption, message code generation, secured flash memory for secured storage Secured communication inside or outside the vehicle (wired or wireless) Encryption with different algorithms demo Decryption in both hardware (HSM) or software comparison Links High End Body Control Module Central Gateway / In-Vehicle Networking Block Diagram  

Description Drones, Rovers, and other Unmanned Vehicles (UVs) are being utilized across various industries including first responders, municipalities, and agriculture, as well as continued support and system development for the Department of Defense. As time progresses, more exciting practical uses are being uncovered. Whether the system is expected to deliver special payloads or protect people from malicious activities, UV systems require a high level of security, reliability, and performance. Block Diagram Products Category Name Product URL Microprocessor QorIQ® Layerscape Processors Based on Arm® Technology | NXP  Secure Authenticator A1006 | Secure Authenticator IC: Embedded Security Platform | NXP  A71CH | Plug and Trust for IoT | NXP  Motor Controllers (MCU) Arm® Cortex®-M7|Kinetis® KV5x Real-time Control MCUs | NXP  Arm® Cortex®-M4|Kinetis KV4x Real-time Control MCUs | NXP  i.MX RT1020 MCU/Applications Crossover Processor | Arm® Cortex-M7 | NXP  i.MX RT1050 MCU/Applications Crossover Processor| Arm® Cortex-M7, 512KB SRAM | NXP  i.MX RT1060 MCU/Applications Crossover Processor | Arm® Cortex®-M7, 1MB SRAM | NXP  Motor Controllers (DSC) MC56F84xxx|Digital Signal Controllers | NXP  Performance Level Digital Signal Controllers, USB FS OTG, CAN-FD | NXP  MC56F82xxx | NXP  Radar MCU S32R Radar Microcontroller - S32R27 | NXP  Camera Sensor MCU i.MX RT1050 MCU/Applications Crossover Processor| Arm® Cortex-M7, 512KB SRAM | NXP  BLE MCU Arm® Cortex®-M0+|Kinetis® KW41Z 2.4 GHz Bluetooth Low Energy Thread Zigbee Radio MCUs | NXP  Electronic Speed Controller MCU Arm® Cortex®-M4|Kinetis KV4x Real-time Control MCUs | NXP  Led Driver ASL150ySHN | Single-phase Auto LED Boost Driver | NXP  AVB Switch SJA1105TEL | Five-Ports AVB and TSN Automotive Ethernet Switch | NXP  Battery Monitor MC33772 | 6-Channel Li-ion Battery Cell Controller IC | NXP  Wireless Charger 15 Watt Wireless Charging Transmitter ICs | NXP  Accelerometer Digital Sensor - 3D Accelerometer | NXP  Related Demos from Communities URL Hands-On Workshop: HoverGames Drone - Commercial Open-Source Small Autonomous Vehicle for Robotic Drones and Rovers  An NXP DroneCode Platform for Developing Low-Cost Small Autonomous Vehicles and Leveraging High-Reliability Automotive Components  Related Communities URL HoverGames Drone Challenge 

  Overview Modern aircraft contain dozens of data distribution and processing systems, which can collectively be referred to as Avionics. NXP’s embedded processors have long been the processors of choice in avionics systems due to their balance of performance per watt, IO integration, temperature range, reliability, and production longevity. Many of these solutions also apply to the rapidly evolving field of mobile robotics. Whether your system operates on the ground, under the sea or in the sky, NXP offers a complete portfolio of sensors, controllers and communications solutions. This solution is based on i.MX Applications Processors. This application processor provides multicore solutions for multimedia and display applications with high-performance and low-power capabilities that are scalable, safe, and secure. Block Diagram Products Category MPU Product URL 1 i.MX 8M Family - Arm® Cortex®-A53, Cortex-M4, Audio, Voice, Video  Product Description 1 The i.MX 8M family of applications processors based on Arm® Cortex®-A53 and Cortex-M4 cores provide industry-leading audio, voice and video processing for applications that scale from consumer home audio to industrial building automation and mobile computers. Product URL 2 i.MX6QP: i.MX 6QuadPlus Processor - Quad-Core, High-Performance, Advanced 3D Graphics, HD Video, Advanced Multimedia, Arm® Cortex®-A9 Core  Product Description 2 The i.MX 6QuadPlus family delivers dramatic graphics and memory performance enhancements and are pin-compatible with a broad range of i.MX 6 processors. Product URL 3 i.MX6D: i.MX 6Dual Processors - Dual-Core, 3D Graphics, HD Video, Multimedia, Arm® Cortex®-A9 Core  Product Description 3 The i.MX 6 series of applications processors combines scalable platforms with broad levels of integration and power-efficient processing capabilities particularly suited to multimedia applications.   Category Sensors Product URL 1 PCT2075: I2C-Bus Fm+, 1 Degree C Accuracy, Digital Temperature Sensor And Thermal Watchdog  Product Description 1 The PCT2075 is a temperature-to-digital converter featuring ±1 °C accuracy over ‑25 °C to +100 °C range. Product URL 2 MMA8453Q: ±2g/±4g/±8g, Low g, 10-bit Digital Accelerometer  Product Description 2 The MMA8453Q is a smart low-power, three-axis capacitive micromachined accelerometer with 10 bits of resolution.   Category Power Management Product URL 1 PF4210: 14-channel power management IC optimized for i.MX 8M  Product Description 1 The PF4210 is a high-performance PMIC that is optimized to power low-cost consumer applications with the i.MX 8M family of applications processors. Product URL 2 MMPF0100: 14-Channel Configurable Power Management IC  Product Description 2 The MMPF0100 is suited to all i.MX 6 processors: i.MX 6SoloX, i.MX 6SoloLite, i.MX 6Solo, i.MX 6DualLite, i.MX 6Dual, i.MX 6Quad, i.MX 6DualPlus and i.MX 6QuadPlus. Product URL 3 MC34671: 600 mA Single-cell Li-Ion/Li-Polymer Battery Charger  Product Description 3 The MC34671 is a cost-effective fully integrated battery charger for Li-Ion or Li-Polymer batteries.   Category Switch Product URL 1 NX5P1000UK: Logic controlled high-side power switch  Product Description 1 The NX5P1000 is an advanced power switch and ESD- protection device for USB OTG applications. Product URL 2 CBTU02044: High-speed Two-differential 1-to-2 Switching Chip  Product Description 2 CBTU02044 is a high-speed differential 1-to-2 switching chip optimized to interface with PCIe4.0 for server and client applications.   Category Interfaces Product URL 1 SJA1105EL: Five- Ports AVB Automotive Ethernet Switch  Product Description 1 The SJA1105EL Ethernet switch offers a flexible solution for implementing modular and cost-optimized ECUs capable of supporting any in-vehicle connectivity requirement. Product URL 2 PTN5150: CC logic for USB Type-C applications  Product Description 2 PTN5150 is a small thin low power CC Logic chip supporting the USB Type-C connector application with Configuration Channel (CC) control logic detection and indication functions.   Category Peripherals Product URL 1 PCF85063A: Tiny Real-Time Clock/calendar with alarm function and I2C-bus  Product Description 1 The PCF85063ATL is a CMOS Real-Time Clock (RTC) and calendar optimized for low power consumption. Product URL 2 PCA9955BTW: 16-channel Fm+ I²C-bus 57 mA/20 V constant current LED driver  Product Description 2 The PCA9955B is an I2C-bus controlled 16-channel constant current LED driver optimized for dimming and blinking 57 mA Red/Green/Blue/Amber (RGBA) LEDs in amusement products.   Category Audio Product URL SGTL5000: Ultra-Low-Power Audio Codec  Product Description The SGTL5000 is a low-power stereo codec designed to provide a comprehensive audio solution for portable products that require line-in, mic-in, line-out, headphone-out and digital I/O.   Category Wi-Fi Product URL 88W8997: 2.4/5 GHz Dual-Band 2x2 Wi-Fi® 5 (802.11ac) + Bluetooth® 5 Solution  Product Description The 88W8997 is the industry’s first 28nm, 802.11ac wave-2, 2x2 MU-MIMO combo solution with full support for Bluetooth 5.

  Description NXP Home Appliances is dedicated to provide intelligent, reliable and appealing solutions to make everyday life a bit easier.Home appliances are part of our daily lives and have been evolving with us. Our wireless MCUs add HAN, WiFi and NFC and along our security devices ensure high-quality wireless connectivity. We have a wide range of precise sensors and complete solutions to simply add voice control to any home appliance. From gas cooktops to inductive and RF cooking; electric toothbrushes with low-energy consumption and battery charging; blenders with efficient, reliable and robust motor control, and all of them need to have sensing options and secure connectivity to offer a personalized and optimal experience. Block Diagram Products Category Name 1: MCU Product URL 1 Arm Cortex-M4|Kinetis KE1xF 32-bit 5V MCUs | NXP  Product Description 1 Kinetis KE1xF MCUs are the Kinetis E high-end series MCUs, providing a robust 5V solution with the high-performance Arm® Cortex®-M4 core running at up to 168 MHz. The KE1xF features a Flextimer featured 8ch PWM supports 3-phase motor control with dead-time insertion and fault detect.   Category Name 2: Gate Driver Product URL 1 GD3100 | Single-Channel Gate Driver for IGBTs/SiC | NXP  Product Description 1 The GD3100 is an advanced single-channel gate driver for IGBTs/SiC. The integrated Galvanic isolation and low on-resistance drive transistors provide a high charging and discharging current. The GD3100 features SPI for programmability and diagnostics.   Category Name 3: LED Driver Product URL 1 PCA9955BTW | NXP  Product Description 1 The PCA9955B is an I2C-bus controlled 16-channel constant current LED driver optimized for dimming and blinking 57 mA Red/Green/Blue/Amber (RGBA) LEDs in amusement products. The PCA9955B works at 31.25 kHz with a duty cycle that is adjustable from 0 % to 100 % to allow the LED to be set to a specific brightness value.   Category Name 4: AC/DC Product URL 1 TEA19363LT: GreenChip SMPS Primary Side Control IC with QR/DCM Operation and Active x-Capacitor Discharge  Product Description 1 The TEA19363LT is a member of the GreenChip family of controller ICs for switched mode power supplies.   Category Name 5: Small Engine Control Product URL 1 MC33813: One Cylinder Small Engine Control IC  Product Description 1 The NXP® MC33813 is an engine control analog power IC delivering a cost-optimized solution for managing one and one-cylinder engine. Category Name 6: Temperature Sensor Product URL 1 PCT2075: I2C-Bus Fm+, 1 Degree C Accuracy, Digital Temperature Sensor And Thermal Watchdog  Product Description 1 The PCT2075 is a temperature-to-digital converter featuring ±1 °C accuracy over ‑25 °C to +100 °C range. Related Documentation Document URL Title https://www.nxp.com/docs/en/application-note/AN5380.pdf  Using FTM, PDB, and ADC on KE1xF to Drive Dual PMSM FOC and PFC Tools Tools URL TWR-KE18F|Tower Development Board|Kinetis® MCU | NXP  Training Training URL Power Regulation/Market Trend and Overview of NXP AC/DC Power Solutions  Advanced Analog Solutions 

Demo         This was a super fun project to work on and is popular around the office and on the road.  Now I have two of these for a truly amazing barrage of Nerf darts!  It's also always a lot of fun to tear things down and the Nerf gun had some cool plastic work and the shooting mechanism is more simple than what I originally guess.  But I digress, this post is about how you can build one of these yourself.  Please leave any questions or comments in the section below and I will try to answer and make refinements to this guide as we go.   The shopping list (aka Bill of Materials or BOM)   If you shop around you might be able to find better prices or substitute parts.   Type Part Qty Price URL UBEC HKU5 1 $             5.33 http://www.hobbyking.com/hobbyking/store/__16663__HobbyKing_HKU5_5V_5A_UBEC.html LiPo TURNIGY 2200mAh 3S 20C 1 $             7.89 http://www.hobbyking.com/hobbyking/store/__8932__Turnigy_2200mAh_3S_20C_Lipo_Pack.html Servo S5030DX 1 $           28.63 http://www.hobbyking.com/hobbyking/store/__18862__Hobbyking_S5030DX_Digital_MG_Servo_X_Large_HV_164g_0_20s_30kg.html Servo HK15138 1 $             3.12 http://www.hobbyking.com/hobbyking/store/__16269__HK15138_Standard_Analog_Servo_38g_4_3kg_0_17s.html Relay PCB COM-11041 1 $             3.95 https://www.sparkfun.com/products/11041 Relay Components Various 1 $             3.00 https://www.sparkfun.com/wish_lists/36307 Nerf Gun Nerf Dart Tag Swarmfire Blaster 1 $           44.99 http://www.toysrus.com/product/index.jsp?productId=11267568 Controller FRDM-K64F 1 $           29.00 FRDM-K64F | mbed Servo Arm Double Servo Arm X-Long 1 $             3.20 http://www.hobbyking.com/hobbyking/store/__19468__CNC_Alloy_Double_Servo_Arm_X_Long_Futaba_.html Servo Arm Heavy Duty Alloy Arm 1 $             5.63 http://www.hobbyking.com/hobbyking/store/__18350__Heavy_Duty_Alloy_1in_Servo_Arm_Futaba_Red_.html Servo Linkage Alloy Pushrod with Ball-Link 65mm 1 $             2.10 http://www.hobbyking.com/hobbyking/store/__25834__Alloy_Pushrod_with_Ball_Link_65mm.html Lazy Susan Shepherd 6 in. Lazy-Susan Turntable 1 $             4.49 http://www.homedepot.com/p/Shepherd-6-in-Lazy-Susan-Turntable-9548/100180572#.UYk5UqLql8E Metal Rod 3/8 in. x 36 in. Zinc Threaded Rod 1 $             2.87 http://www.homedepot.com/p/3-8-in-x-36-in-Zinc-Threaded-Rod-17340/202183465#.UYk5pqLql8E Frame 1/2 MDF 2ftx4ft 1 $           10.45 http://www.homedepot.com/p/1-2-in-x-2-ft-x-4-ft-Medium-Density-Fiberboard-Handy-Panel-1508108/202089097?N=btn1#.UYk6CqLql8E   The build   Two main pieces to construct in this phase.  The base turret and the actual hacking of the Nerf gun.   All your base.. The base of the turret is pretty rudimentary, lot's of room for improvement here.  I used 1/2 MDF and some carpentry skills.  Here is some instruction on how to build a MDF box.  Atop the box is a lazy Susan (ball bearing ring) so that the top-plate can rotate smoothly.  We considered leaving this element out, but worried that it would put to much strain on the servo.   On the subject of servos, a few tidbits of wisdom for you as you build this thing.  First, the left/right servo needs to be dead center of the lazy susan, if your off too much things will start to bind which is not good for your servo.  Second, I used large higher torque servos which cost a bit more, they might be overkill, but it certainly performs well.   I did a quick dimensionally accurate rendering of the design in Sketchup. Files are here.   Hacking the Nerf   Now for the fun stuff.   There is no shortage of screws with this Nerf Gun.  So get out your Phillips screwdriver and go to town. There are two electrical systems in the Nerf that we are going to tap into.  One is the power switch and the other is the electrical trigger. This is the electrical trigger.  The trigger goes to our relay, which is either on or off.  We did try at first to use a 7.2V R/C car battery, but the Nerf draws too much power and didn't fire.  Going up to a 11.1V LiPo fixed that right up. This is the power switch. In Nerfinator 1.0 everything was hardwired together, which prevented us from completely pulling the Nerf from the base and made repairs difficult to say the least.  Nerfinator 2.0 we put this handy connector which allowed us to completely and easily remove the Nerf from the base.  Shipping this thing around the country will take a toll on it!  On that subject, Nerf 1.0, stopped cycling to the next position for us at the Austin Mini Maker Faire.  After a through inspection of the operational mechanics inside the Nerf (really cool BTW) it was a little bitty spring that was causing the piston not to fully retract.  We replaced the spring with 1/2 a ballpoint pin spring and to our surprise it all worked again. Electrical Connection Diagram   Added High-Level Block Diagram.  Need to add pinouts.  You'll have to read the code for now to figure it out.     Code   Mbed was the programming tool of choice for this build.   Receive Side (RX) - The receiver is the base side.  This one takes input from the remote and controls the servo movement. NerfGun_nRF24L01P_RX - a mercurial repository | mbed Transmit Side (TX) - The transmitter is the remote side.  This one senses the users movement (accelerometer) and sends that data to the base station. NerfGun_nRF24L01P_TX - a mercurial repository | mbed   Finishing Touches   In the first passes of this build we just used a bare development board as the remote control.  We found that when given the remote they would not orientate it properly, so 3D Printed Controller STL files   Development Team John McLellan - Amplification/Motivation Clark Jarvis - Software/Hardware Iain Galloway and Angus Galloway - Design and print of controller FRDM_case_sunday_PART_REV_001.STL.zip

Wind River's Ka Kay Achacoso demonstrates VxWorks 7 with graphics on the i.MX6 series applications processor. Features Demonstration of Graphics using VXWorks 7 The drivers are taking advantage of the i.MX processor's GPU to render hardware accelerated 3D graphics Using the accelerometer to show the orientation of the board The display shows a 3D view of how the board is being positioned taking into consideration perspectives and lighting shadows Featured NXP Products ARM® Cortex®-A9 Cores: i.MX 6 Series Multicore Processors Links NXP Connect - Wind River

Demo Owner: Michael L Dow   NXP's Metropolitan Area Network Demonstration Kit utilizes the latest IPv6 Mesh technologies and enables the Smart City of the future. This kit was built around a Smart Objects modem and IPv6 stack from Nivis based on the Kinetis K60 and the MC12311 sub-GHz radio. In this demo the Power PC P1025 Tower board acts as a Data Concentrator/Edge Router, gathering information from several battery powered wireless Smart Object end nodes—all managed via a Nivis’s Network Manager Software.       Features Sub- 1 GHz communication Metropolitan  Area Network Communication Featured NXP Products QorIQ Processing Platforms - P1025 MC12311 Kinetis K60 Development Hardware Used TWR-METRO-KIT Design Resources Demo Quick Start Guide Link to Nivis web page  

  Overview   NXP ®  offers PowerQUICC ® . and ColdFire ® . processors and a large selection of 8-bit MCUs that support common point-of-sale (POS) printer applications for retail and services industry customer receipts. Benefits include Low cost and complexity OS support to control print-heads, paper handling, character management, scanner inputs Management of digital/analog inputs and controls Multiple connectivity options Flexibility to address multiple mixed-feature applications   Block Diagram     Recommended Products   Category Name MCU and MPU 32-bit Microprocessor with USB On-The-Go, Ethernet, PCI, DDR2/DDR controller and Encryption | NXP  32-bit MPU, 10/100 ETH, USB OTG, PCI. i.MX258 Processors|Point of Sale (POS) | NXP  400 MHz Arm9®, SVGA, 10/100 ETH, CAN, tamper detection, <1W i.MX28 Applications Processors: Integrated Power Management Unit (PMU), Arm9™ Core | NXP  454 MHz Arm9®, SVGA, 10/100 ETH, CAN, PMU, <1W i.MX 6Solo Applications Processors | Single Arm® Cortex®-A9 @ 1GHz | NXP  1 GHz Arm® Cortex™-A9, 2xWXGA, graphics, video, 10/100/1000 ETH, CAN, PCIe, PMU 8-bit Flexis QE MCUs | NXP  Flexis Low-Power 8-bit MCU 4-128K Flash.   Category Name Power Management 3.0A 1.0MHz DDR Switch-Mode Power Supply | NXP  Li-Ion Battery Charger, DDR Switch-Mode Power Supply (3.0A, 1MHz).   Category Name Signal Conditioning MC33972 | MSDI with Suppressed Wakeup | NXP  Switch Detector 22 contacts. MSDI | NXP  Switch Detector 22 contacts.   Category Name Print Sensor 0 - 10kPa Integrated Pressure Sensor | NXP  Sensor On-Chip Signal Conditioned, Temperature Compensated and Calibrated.   Category Name Motor Driver MC33880 | Octal Serial Switch with SPI | NXP  Configurable Octal Serial Switch (LSS / HSS) for Motor Drive. MC34931 | H-Bridge, Brushed DC Motor Driver | NXP  H-Bridge Brushed DC Motor Driver, 5-28V, 5A, 11kHz MC34932 | H-Bridge, Brushed DC Motor Driver | NXP  H-Bridge Brushed DC/Stepper Motor Driver, 5-28V, 5A, 11kHz MC33886 | H-Bridge, Brushed DC Motor Driver | NXP  H-Bridge Brushed DC Motor Driver, 5-28V, 5A, 10kHz MC33926 | H-Bridge, Brushed DC Motor Driver | NXP  H-Bridge Brushed DC Motor Driver, 5-28V, 5A, 20kHz Dual H-Bridge Motor Driver 2-8.6 V 1.4 A 200 kHz | NXP  H-Bridge Brushed DC/Stepper Motor Driver, 2-8.6V, 1.4A, 200kHz H-Bridge DC Motor Driver 2-15 V 3.8 A 200 kHz | NXP  H-Bridge Brushed DC Motor Driver, 2-15V, 3.8A, 200kHz   Documentation   Application Notes: Simplified EHCI Data Structures for the High-End ColdFire ®  Family USB Modules https://www.nxp.com/docs/en/application-note-software/AN3522.pdf

This post entry provides a detailed description of the OM29263ADK kit, a new antenna tuning development kit specially designed to facilitate the NFC antenna prototyping process. This document has been structured as follows: OM29263ADK kit contents This kit consists of a single PCB board that includes:  A pre-matched antenna of 2 turns and a size of 77 by 113 mm.  A second pre-matched antenna of 4 turns and a smaller size of 20 by 20 mm.  And, 8 extra boards to prepare the matching for custom antennas. As a result, this kit is a perfect resource for different purposes such as evaluating the RF performance of different antenna sizes and, for prototyping your custom antenna quickly. In addition, this NFC antenna development kit is compatible with our existing product support package. You can directly connect it to CLRC663 demoboards, as well as to PN5180 and PN7462 demoboards after a minor tuning. Using OM29263ADK kit with CLEV6630A or CLEV6630B The process is really straightforward… First, take one CLRC663 demoboard and separate the main PCB from the antenna & matching circuit. The board includes cut lines, so you can divide both sections easily by only using your hands. Second, break the kit OM29263ADK PCB so that you separate the pre-matched antenna from the other PCB parts. Then, it is just a matter of connecting the two parts together. The kit antenna includes pin male connectors while the CLRC663 board includes the corresponding female connectors. Therefore, hook up the antenna with the main board, solder the connectors and that’s all. We can observe that when we connect the kit large antenna to the reader PCB, the  impedance measured with our network analyzer shows that the tuning is adjusted to approximately, 19 Ohms. This is the result obtained without any hardware modification The same process applies for the smaller antenna: Similarly, we can observe that when we connect the kit small antenna to the reader PCB, the  impedance measured with our network analyzer shows that the tuning is adjusted to approximately, 36 Ohms. This is the result obtained without any hardware modification: Using OM29263ADK kit with PNEV5180B or PNEV7462C In case you are interested to connect the OM29263ADK kit antennas to the PNEV5180B or PNEV7462C boards, the preparation process is the following: First, separate the antenna and the matching section from the PN5180 or PN7462 demoboards, as before, using the cut lines. Then, take one kit sample, and separate the pre-matched antennas for the other PCB parts. And finally, adjust the EMC filter. The EMC filter adaptation is required because the kit antenna is prepared for asymmetric tuning while the PN5180 and PN7462 original antenna use a symmetrical tuning. The main difference between both types of tuning is the cut off frequency. The symmetric tuning uses a cutoff frequency around 15MHz, while the asymmetric can go up to 22 MHz. In practice, for this adaptation, we only need to change the value of the capacitor C0 in the main board. For instance, the existing 220 pF capacitor can be replaced for another one of 68 pF. Using OM29263ADK kit to connect your own antenna coil This section describes how to use the kit PCB boards for our custom antenna tuning. For this task, the list of material that we need is: A reader PCB board, in the example, we picked CLRC663 One of the PCBs for antenna matching included in the kit And, the any antenna to be matched  In our case, we have selected one sample antenna available in our lab. The following explanation will be guided using this antenna as a reference, but any antenna can be tune using the same process. The usual list of steps to tune a custom antenna are: First, we need to define target impedance and Q factor, as design parameters for our reader Then, we will characterize the antenna coil and find its parameters After that, we will design the EMC filter With this, we will calculate the matching components using an Excel sheet Afterwards, we will assemble the calculated components and measure the first results. We will take field measurements, which probably will show that it is not perfect, so we may need to adapt the matching values With these fine-tuned vales, we will re-assemble again And finally, we will design the receiver circuit. Define target impedance and Q-factor First, we start defining the target impedance and Q-factor. The target impedance is a design parameter, which needs to be chosen according to our needs whether we want to go for maximum field strength or minimum battery consumption or a trade-off in between. Typically, reasonable values are between 20 Ohms and 80. Another important design parameter is the Q factor. The Q factor is a dimensionless parameter indicating the performance of a resonant circuit. The higher the Q factor, the higher the read range. On the other hand, increasing the Q factor also reduces the bandwidth of the circuit. As a result, in practical implementation, Q-factor values below 30 are demonstrated to fit well for the ISO14443 wave form timing requirements and corresponding spectrum.  For our tuning exercise, the design parameters chosen are an impedance of 20 ohms and a Q factor of 25 Measure antenna coil Next step is to characterize the antenna coil. Any antenna coil has an input impedance. This input impedance is complex and consists of an inductance, capacitance as well as some losses represented by a resistance (R). The actual values depend, among others, on antenna material, thickness of conductor, distance between the windings, number of turns, etc.  The coil characterization needs to be done with a network analyzer. It could be a high end, such as Agilent or Rohde & Schwarz, which is powerful, accurate, easy to use, but expensive. Or we can also go for low end solutions, such as the miniVNA PRO, which is cheap compared with the previous ones, and accurate enough for our needs. In our case, the characterization of our lab antenna shows:  An inductance around 1.3 uH And a resistance of 2.5 Ohms Design EMC filter The next step is to design the EMC filter. As we are using CLRC663, we will go for an asymmetric antenna tuning. Good inductor values are between 330nH and 560nH. and 21MHz cutoff frequency is ideal for asymmetric tuning. Fixing this two parameters, we can easily calculate the required capacitor component for our EMC filter with the formula below. In our example, we need to use a capacitor of C= 122 pF. With this, we just pick up the closer commercial value from our components box Calculate matching circuit components We have characterized the antenna coil and completed the EMC filter. Now, we can calculate the matching network components. The matching components need to be calculated so that the maximum power from the reader is transmitted to the antenna. This happens when the equivalent impedance seen from the reader IC only has the real part, without the complex part. There are some complex calculation involved in the process. In order to avoid these cumbersome formulas, NXP provides a useful Antenna Tuning excel sheet that calculate the appropriate components for you. Below, you can see a screenshot of the Excel sheet in the slide. This sheet calculates C1 and C2 matching values according to the inputs expected from the user. These are The measured antenna coil parameters The EMC filter parameters. The target impedance and Q-factor of our design With these values, The Excel sheet calculates and outputs the value of the matching components: C0, C1, C2 and Rs. In our exercise, the output values calculated for the matching network by the Excel sheet are C1 around 43 pF and C2 around 144 pF Assemble and measure Typically, the calculated values do not match with commercial components. The easiest way is to add components in parallel to get as close as possible to the calculated values. If we take a closer look to the kit antenna matching PCB board, the pad location is the following: We have two slots for C0 – so we can have two capacitors in parallel to achieve a better accuracy on the capacitance value we need to achieve We also have two slots for C1, for the same purpose We have two more slots for C2 soldering We also have two slots for the dampening resistor, in case we need to reduce the Q-factor of our antenna. And finally, one slot for the receiver resistor circuit. After the first component assembly, it is worth performing a field measurement to find out how accurate our matching is in reality. Typically, the measured impedance is different than the impedance calculated in the simulation. Therefore, the calculated matching components were not 100% accurate. But we knew that in advance. We were aware that we were just getting a rough approximation to the antenna parameters. As a result, a good matching is achieved after a number of iterations according to the field measurements that we obtain. As a general rule,  C1 changes the magnitude of the matching impedance and C2 changes its imaginary part. In our exercise, after soldering the first components, the equivalent impedance is around 19 Ohms but it also has a significant imaginary part. As a result, it can be fine-tuned towards better performance. We modified C1 and C2 a couple of times until we found out the final values that work better. obtaining a impedance with only real part at 22 Ohms (C1= 36pF and C2=154 pF). Adjust receiver circuit The last step of tuning our antenna is to design the receiver circuit. The Rx circuit that consists of a voltage divider and a coupling capacitor connected from the output of the EMC filter to the RX pins of the NFC reader. The objective is to set the voltage level at the reception pins to achieve the compromise between a good sensitivity. For CLRC663 plus, the serial resistor is in the range of 7 and 15 kΩ. You can start with a 11 KOhm value, then, the resistor can be adjusted depending on the voltage measured in the Rx pins. If the voltage at Rx pin is higher than 1.7 V, it is recommended to increase the resistor value and if the voltage at Rx pin is below than 1.2 V, it is recommended to decrease the resistor value. Using OM29263ADK kit to evaluate the performance of different antenna shapes The section covers how you can use the antennas included in the kit for performance comparison. Please note that this lab exercise is shown only for illustrative purposes on how the kit can be used to evaluate the performance of different antenna shapes. As an example, we defined a sample scenario where we want to characterize how the field strength decreases with distance when using antennas of different size. For that, we used the following setup: A class 1 ISO14443 Reference PICC A scope A CLRC663 board connected to the small antenna A CLRC663 board connected to the large antenna A ruler to measure the distance The measurements were taken in this way: We tuned the large and small antennas to 20 Ohms We connected the board to the laptop, and we executed the NFC Cockpit tool to control the RF field. We measured with the scope the voltage level obtained by the ISO14443 Class 1 Reference PICC while we increased the distance. Background information Before actually showing you the results, it is worth it to review a couple of antenna design principles to properly understand the results. Coupling coefficient Before actually showing you the results, it is worth it to review a couple of antenna design principles to properly understand the results. The coupling coefficient is a parameter that indicates how much of the magnetic field generated by the reader is picked up by the card. The coupling coefficient takes a value between 0 and 1 If the coupling equals 1, it means we have a perfect coupling, all magnetic field lines are picked by the card If the coupling equals 0, it means we have no coupling at all, no magnetic field lines are picked by the card The key message is that the coupling coefficient is just a geometric quantity. It depends on: The reader and card antenna dimensions (both antenna radius) Their relative position (whether in parallel or perpendicular, they will pick a different amount of magnetic field lines) The distance between them And the magnetic properties of the medium Mutual inductance Very related to the coupling coefficient, we have the mutual inductance. The mutual inductance allows us to determine the voltage induced in the card antenna, that depends on: Coupling coefficient  Better coupling, higher the voltage Driver current  The higher the current we drive in the reader antenna, the stronger the magnetic field Antenna inductance Precisely, in this setup, we are going to measure the voltage perceived by the reference PICC when using two different antennas. Antenna tuning components used for the large antenna First, we prepared a tuning of 20 Ohms in the large antenna. This task was done using the process described above. As an example, we selected a low Q-factor of 10, which helped us to accommodate high bit rates for ISO14443. In the figure below, you can see the components we assembled to tune the large antenna near to 20 Ohms. Antenna tuning components used for the small antenna Second, we prepared a tuning of 20 Ohms in the small antenna so that the results are comparable. The same Q-factor and EMC filter values were used, but obviously, as the antenna size is different, we used different C1, C2 and Rs values to achieve the same equivalent impedance OM29263ADK large antenna vs small antenna The following graph shows the results we obtained: The blue line, represents the DC output voltage obtained from the Class 1 Reference PICC as we increase the distance from the reader using the large antenna… The green line, represents the DC output voltage obtained from the Class 1 Reference PICC but using the reader with the small antenna connected. As a result, what we see is that at close distance, both antennas are able to deliver the same field strength. However, as distance increases, the RF field of the small antenna starts to attenuate quickly from 2 cm distance of the reader while the RF field of the large antenna is more or less stable until 5 cm, after that, it starts to attenuate quickly as well. Potentially, what we can conclude is that for this setup, we might be able to get more reading distance with the large antenna. ISO/IEC14443 vs ISO/IEC15693 reader - Quality factor We need to bear in mind that our antenna is not only for energy transfer, but also it should match with the waveform requirements. Therefore, from the practical point of view, the Q factor of the system is limited by the bandwidth as if we increase the Q, we increase the field strength but we decrease the bandwidth. Our reader can be optimized whether we are designing a reader for ISO14443 or ISO15693 as the signals modulation and timing requirements of the rise and fall times for both RF protocols are different. Actually, in practice, ISO15693 allows us a higher Q factor because there is a lower bandwidth requirement as the waveform timings are more relaxed and, the power transfer requirement is lower than ISO14443. For such optimization, you can refer again to NXP antenna tuning excel sheet. If you recall, one of the input fields of the excel sheet is the Q-factor. Therefore, you can introduce here a value below 30 for ISO14443 readers or below 100 for ISO15693 readers. The excel will output reasonable matching values for the first components adjustment. After that, you can do a fine tuning according to the process I explained before. Further information You can find more information about NFC in: Our NFC everywhere portal: https://www.nxp.com/nfc You can ask your question in our technical community: https://community.nxp.com/community/identification-security/nfc You can look for design partners: https://nxp.surl.ms/NFC_AEC And you can check our recorded training: http://www.nxp.com/support/online-academy/nfc-webinars:NFC-WEBINARS Video recorded session On 21 June 2018, a live session explaining this topic. You can watch the recording here:

This project include the codes and doc to support optimize the EMI of S32G by frequency changing and SSC. Contents as follows: 目录 1 展频的基本概念 ......................................................... 2 2 获取测试用uboot源代码 ............................................. 5 3 DDR_PLL的改频 ........................................................ 5 4 DDR_PLL的展频 ........................................................ 9 5 总结修改后的源代码 ................................................ 17

This demo shows the interaction among MCUs, motor drivers, and sensors using simple mbed code and various communication protocols, namely Ethernet, I2C, and PWM to simulate real-world applications on a smaller scale       Features Motor driver with Brushed DC motor driver with current feedback and thermal regulation 6-Axis sensor FXOS8700 (Accelerometer + Magnetometer) and 3-Axis Gyroscope FXAS21002 Kinetis K64 MCU 120 MHz ARM® Cortex®-M4 core with Ethernet and USB Complete system consisting of an MCU, a sensor, and a motor driver _______________________________________________________________________________________________________   Featured NXP Products Product Link Sensor Toolbox Development Boards for a 9-Axis Solution using FXAS21002C and FXOS8700CQ https://www.nxp.com/design/development-boards/freedom-development-boards/sensors/sensor-toolbox-development-boards-for-a-9-axis-solution-using-fxas21002c-and-fxos8700cq:FRDM-STBC-AGM01?&lang_cd=en Freedom Expansion board for MC34931- Brushed DC Motor Driver, H-Bridge, 20kHz https://www.nxp.com/design/development-boards/analog-toolbox/freedom-expansion-board-for-mc34931-brushed-dc-motor-driver-h-bridge-20khz:FRDM-34931S-EVB?&lang_cd=en Freedom Development Platform for Kinetis® K64, K63, and K24 MCUs https://www.nxp.com/design/development-boards/freedom-development-boards/mcu-boards/freedom-development-platform-for-kinetis-k64-k63-and-k24-mcus:FRDM-K64F?&lang_cd=en _______________________________________________________________________________________________________   Software Links Accelerometer code Motor driver code   For more detailed information about this demo, please download attached PDF

Overview This reference design demonstrates the design of a 3-phase AC induction motor drive with volt per hertz control and supports the NXP® 56F80X and 56F83XX Digital Signal Controllers (DSCs) dedicated for motor control applications. Designed as a low-cost high volume motor drive system for medium power three-phase AC induction motors and is targeted for applications in both industrial and appliance fields The drive runs in a speed closed loop using a speed sensor According to the state of the control signals (Start/Stop switch, speed up/down buttons or PCMaster set speed) the speed command is calculated using an acceleration/deceleration ramp Features Speed Control of 3-phase AC Induction motor with quadrature volt per hertz control Targeted for 56F80X, 56F83XX, and 56F81XX Digital Signal Controllers Running on a High Voltage Medium Power Board for Three Phase Motors Volt-per-Hertz control with a speed closed loop Option to run the motor in open loop Quadrature encoder for motor speed reference Manual interface PC master software control interface and monitor Fault protection Block Diagram Board Design Resources

this doc explain the HSE crypto driver and how to develop new feature 目录 1 参考资料 .................................................................... 2 1.1 参考资料 ................................................................. 2 1.2 版本匹配说明 .......................................................... 3 2 HSE FW服务 ............................................................. 3 2.1 服务描述符 ............................................................. 3 2.2 服务编号 ................................................................. 4 2.3 服务请求和响应 ...................................................... 6 2.4 服务执行 ................................................................. 9 2.5 Crypto驱动AES示例使用到的服务 ........................ 18 3 环境搭建 .................................................................. 19 3.1 安装与编译 ........................................................... 19 3.2 运行Demo ............................................................ 21 4 Crypto驱动代码与功能说明 ...................................... 23 5 定制1：增加GetAttribute功能 .................................. 28 6 CmacCtr Demo简介 ................................................. 31 7 SymmetricPrimitive Demo简介 ................................ 32 8 总结 ......................................................................... 34 9 其它注意事项 ........................................................... 34

本文说明在S32G2 RDB2板上实现LLCE to PFE Demo的搭建过程。本Demo目前包括：  CANtoEth：CAN0发送，用硬件回环到 CAN1接收，然后通过PFE_EMAC1， 再通过RGMII接口发出。  CANtoEth：CAN0发送，用硬件回环到 CAN1接收，然后通过PFE_EMAC1， 再通过SGMII接口发出。  EthtoCAN：PC通过PFE_EMAC1的 RGMII发出，接收到CAN1，再硬件 回环到CAN0  CANtoCAN Logging to Eth: CAN0发 送，用硬件回环到CAN1接收，然后 通过PFE_EMAC1，再通过SGMII接 口发出,同时LLCE内部硬件把CAN1 再发送到CAN15_TX，再用硬件回环 到CAN14_RX 软件版本为 RTD3.0.0+LLCE1.0.3+PFE0.9.6/0.9.5。

This doc explain our Mcal driver and how to custome them. contents as follows: 目录 1 AutoSAR MCAL基本概念 .......................................... 2 1.1 AutoSAR目标 ......................................................... 2 1.2 AutoSAR概念 ......................................................... 2 1.3 AutoSAR基本方法 .................................................. 2 1.4 BSW(Basic Software) ............................................. 4 1.5 NXP Basic AutoSAR软件 ....................................... 4 1.6 RTE与BSW的配置 ................................................. 5 1.7 BSW的配置流程 ..................................................... 6 1.8 MCAL驱动 .............................................................. 7 2 MCAL工具 ................................................................. 7 3 MCAL说明 ................................................................. 8 3.1 MCAL的下载与说明 ................................................ 8 3.2 EB Tresos的下载，安装 ....................................... 13 3.3 RTD-MCAL安装 ................................................... 16 3.4 Trace32的下载与安装 .......................................... 18 3.5 样例工程的编译，运行 ......................................... 20 4 MCAL驱动配置与定制 ............................................. 40 4.1 MCU ..................................................................... 45 4.2 PORT ................................................................... 59 4.3 DIO ....................................................................... 69 4.4 FlexCAN ............................................................... 71 4.5 FlexLin ................................................................. 87 4.6 GMAC .................................................................. 93 4.7 I2C ..................................................................... 101 4.8 PMIC .................................................................. 108 4.9 PMIC WDOG ...................................................... 127 4.10 WDOG ............................................................... 137 4.11 UART ................................................................. 144 4.12 SPI ..................................................................... 149 4.13 PWM .................................................................. 165 4.14 ADC ................................................................... 171 4.15 Thermal .............................................................. 177

Overview   As gaming application needs real time, quick and fast reaction, user would like to have low latency solution for gaming application. Existing BT solution has higher latency. Also power consumption is critical in the design with limited battery capacity. NXP’s gaming headset solution combined with low latency and lower power consumption than competitors. We provide two platforms. One use KL27 MCU and the other one use LPC5528 MCU as processor. The key different feature between these two MCU platform is the audio resolution support. KL27 platform supports 48K sampling rate and LPC5528 platform supports USB audio up to 96K sampling rate. We design USB dongle and headset side solution, either module or Arduino interface H/W design. Also PMIC is important in the headset side. NXP can provide MCU, BLE and PMIC for this application. Block Diagram Products Category MCU Product URL 1 KL2x: Kinetis® KL2x-72/96 MHz, USB Ultra-Low-Power Microcontrollers (MCUs) based on Arm® Cortex®-M0+ Core  Product Description 1 The Kinetis® KL2x is an ultra-low-power MCU family that adds a full-speed USB 2.0 On-the-Go (OTG) controller or a full-speed crystal-less USB 2.0 device controller in addition to the Kinetis KL1x series. Product URL 2 LPC552x/S2x: Mainstream Arm® Cortex®-M33-based Microcontroller Family  Product Description 2 The LPC552x/S2x MCU family further expands the world’s first general purpose Cortex-M33-based MCU series   Category Power Management Product URL PCA9420: PMIC for Low Power Applications  Product Description The PCA9420 is a highly integrated Power Management IC (PMIC), targeted to provide power management solution for low-power microcontroller applications or other similar applications powered by Li-ion battery.   Category Wireless Product URL NXH3670: Ultra-low Power, Low Latency Audio for Wireless Gaming Headphone  Product Description The NxH3670 constitutes a highly integrated, single-chip ultra-low-power 2.4 GHz wireless transceiver with embedded MCU (Integrated Arm® Cortex®-M0 processor), targeted at wireless audio streaming for gaming headphones, delivering low latency audio and ultra-low power consumption.