Overview This reference design is a 3-phase brushless DC (BLDC) motor sensorless drive for fans, pumps and compressors based on the low-cost NXP® 56F801x digital signal controllers (DSCs). The concept is a closed-loop speed-controlled BLDC drive with no need for position or speed sensors AIt serves as a reference design for a BLDC motor sensorless control system, ideal for fan, pump and compressor applications Power stages used by the application are designed for 12V DC line voltage and 3Aor 8A output current The reference manual provides a detailed description of the application, including design of the hardware and the software Features 3-phase brushless DC motor sensorless drive Designed to fit into fan, pump and compressor applications Uses 56F8013 32 MIPS Digital Signal Controller Available for two power stages and two motors Input power supply voltage +12 VDC for power stages Control techniques incorporate: Sensorless, trapezoidal control of 3-phase BLDC motor with back-EMF sensing ADC zero crossing sensing for sensorless control Closed-loop speed control using PI controller Adjustable DC-bus current limitation PI controller Motoring mode Both directions of rotation Speed range: 200-2000 and 800-8000 RPM (depending on the motor used) Manual interface (RUN/STOP switch, UP/DOWN pushbuttons) FreeMaster interface for monitoring, controlling and tuning Fault protection (DC-bus over-current, DC-bus under-voltage, DC-bus over-voltage) Automatic calibration of phase back-EMF measurements 20 kHz PWM switching frequency Easy to tune for different power stages and motors. Block Diagram Board Design Resources

Overview The Occupancy Sensor Node reference design is a compact form factor, open source design. It enables low power nodes based on IEEE 802.15.4 protocols such as Thread and ZigBee to communicate data to a wireless sensor network. NXP supplements the Kinetis KW2xD with tools and software that include hardware evaluation and development boards, software development IDE and demo applications and drivers. Features MKW24D512 802.15.4 Kinetis MCU Full IEEE 802.15.4 compliant wireless node for Thread network Integrated PCB meander horizontal antenna 2 Interrupt push button switches (LLWU) 1 FXOS87000CQ Combo sensor 1 Coin cell battery holder 1 EEPROM 1 Battery charger Block Diagram Board Design Resources

Overview With over 35 million installed nodes, PROFIBUS is the world’s most successful communication technology used in industrial automation. Its growth and expansion is aided by the addition of PROFIBUS functionality to PowerQUICC® and QorIQ® communications processors. Integration of PROFIBUS Layer 2 creates a single-chip solution with a direct connection to a RS485 transceiver, eliminating cost and board space associated with an external PROFIBUS ASIC NXP® offers PROFIBUS Layer 2 firmware for PowerQUICC and QorIQ processors with a QUICC Engine® controller, eliminating the need for a costly PROFIBUS ASIC and leaving the processor core almost entirely free for processing Features PROFIBUS Reference Platform supports PROFIBUS Slave certified by ComDec, a PROFIBUS certification lab hosted by Siemens AG PROFIBUS Master Eliminates costly PROFIBUS FPGA or ASIC by running PROFIBUS Layer 2 (FDL) on QUICC Engine ®  controller hardware integrated inside the MPU Protocol and customer control application can run simultaneously on one chip Commercial PROFIBUS slave stack available from Technologie Management Gruppe (TMG) Evaluate using Tower ®  System modules (TWR-P1025-KIT) QorIQ ®  P1, T1 and LS1 processors can also provide simultaneous support for Industrial Ethernet protocols like PROFINET, EtherCAT and EtherNet/IP ™ PowerQUICCC MPC8309 processor delivers an impressive 835 DMIPS core performance for less than 1.6 watts Block Diagram Get Started Getting Started With NXP PROFIBUS for PowerQUICC and QorIQ NXP offers PROFIBUS Layer 2 firmware for PowerQUICC and QorIQ processors with a QUICC Engine controller. The PROFIBUS software supports both Master and Slave modes of operation and can be evaluated on the P1025 processor. Instructions for accessing the hardware evaluation platform and the software are given below. PROFIBUS for PowerQUICC and QorIQ can be evaluated using TWR-P1025-KIT To build/install/load the PROFIBUS software you will need CodeWarrior for Power Architecture V10.3 The PROFIBUS Slave package includes the following: CodeWarrior for Power Architecture V10.3 project archive containing: QUICC Engine PROFIBUS microcode (binary) PROFIBUS Layer 2 driver example (source code) PROFIBUS Layer 7 stack (binary provided by TMG) A sample application (source code) The /Docs folder of the project contains: Readme file Release Notes PROFIBUS Microcode User Manual NXP PROFIBUS Slave Layer 2 API description Sample test logs Software Getting Started Guide Hardware Getting Started Guide Design Resources

Block Diagram The NXP® P2020-MSC8156 AdvancedMC™ (AMC) reference design is a multi-standard baseband development platform for the next generation of wireless standards such as LTE, WiMAX, WCDMA and TD-SCDMA. This AMC platform integrates the QorIQ® P2020 processor with its MSC8156 DSP A P2020 and MSC8156 mezzanine card provide the system building blocks to enable rapid prototyping systems Ideal for developing solutions for the next generation of wireless standards Features Key P2020-MSC8156 AMC Reference Design Features: Single width, full height AMC form factor QorIQ ®  P2020 processor Dual e500v2 cores at 1.2 GHz 1 GB of DDR2 (SOCDIMM) TCP/IP acceleration eSDHC USB MSC8156 DSP Six SC3850 cores, built on StarCore ®  technology, at 1 GHz each Multi Accelerator Platform Engine for Baseband (MAPLE-B) Programmable Turbo and Viterbi decoder Two banks of 512 MB 64-bit DDR3-800 Block Diagram Board Design Resources

Overview The Electro-Mechanical Brake reference design exhibits the suitability and advantages of the NXP® 56F8300 family of DSCs for intensive automotive control applications (hybrid braking like systems) featuring a 3-phase Permanent Magnet Synchronous Motor (PMSM) with an encoder and Hall-effect position sensors. This application uses a vector control approach of the 3-phase PMSM with a dedicated low-voltage (automotive 12V) board comprising MC56F8323 controller, MC33989 system basis chip, MC33982 intelligent single switch, and MC33896 3-phase FET pre-driver The Electro-Mechanical Brake Reference Design is controlled via FreeMASTER control page using RS232/CAN communication Features Application Features Initial position detection Vector current control with position feedback: Hall effect sensor Encoder FlexCAN inter-board communication Overvoltage, undervoltage and overcurrent fault protection PC master control page Target Devices/Platforms Permanent Magnet Synchronous Motor NXP ®  MC56F8323 hybrid controller NXP MC33892 intelligent high current single switch NXP MC33989 system basis chip with high speed CAN NXP MC33896 3-phase FET driver for 12/42V systems Motor Control Application Block Diagram Board Design Resources

Overview The NXP Quick Charge 4+ power bank with 15-watt Qi-certified wireless power output supports all of the latest wired and wireless technologies. Equipped with Qualcomm™ Quick Charge 4+ technology, our power bank provides lightning-fast simultaneous multichannel charging of smartphones, watches, tablets, 2-in-1 products, notebooks and other devices featuring Qualcomm Snapdragon™ mobile platforms and processors. A mere 5 minutes of charging on the NXP power bank delivers 5 hours of battery life. New Power Delivery (PD 3.0) technology combines with a programmable power supply (PPS) in the NXP power bank to support Quick Charge 4+ devices and provide backward compatibility with Quick Charge 2.0 and 3.0 technologies. NXP power bank system software integration also includes wireless power and battery management, PD stacks and more programmable APIs for a fully customizable application. This new power solution leverages the many advantages and standards of USB-C with dual-way USB power delivery for input and output with Quick Charge. Anti-counterfeit and OEM-specific authentication, as well as accurate voltage, current and temperature protection deliver enhanced safety and security. Features Dual-way USB Type-C supports input & output Quick Charge for input and output, PD+PPS, QC2, QC3,QC4 2S battery supported (capability~10,000 mAh), output > 50 W Integrated wireless 15W transmitter supports fast charging for Samsung ®  and Apple ®  devices Digital control buck-boost converter One control IC controls buck-boost converter, charge, Qualcomm algorithm, PD communication and wireless power management Board

Overview The 3-phase PMSM Vector Control using Quadrature Encoder on based on Kinetis® K40 MCUs reference design demonstrates the ability of the Kinetis K40 Arm® Cortex®-M4 MCU to drive the advanced motor control application. Targeted at the NXP® Tower® rapid prototyping system as a hardware development platform. Together with available embedded source code, you can quickly build own industrial drive application. For the successful execution of the vector control algorithm, the information on the motor shaft position is critical. The quadrature encoder position information is known in the entire motor speed range, allowing the motor start with full torque at zero speed. Features Vector control of the PMSM using the quadrature encoder as a position sensor Targeted at the Tower ®  rapid prototyping system (K40 tower board, Tower 3-phase low voltage power stage) Vector control with a speed closed loop Rotation in both directions Application speed range from 0% to 100% of nominal speed (no field weakening) Operation via the user buttons on the Kinetis ®  K40 Tower board or via FreeMASTER software Block Diagram Design Resources

Overview This reference design demonstrates a vector control technique of a 3-phase AC induction motor with a position encoder coupled to the motor shaft. The algorithm runs on Our 56F80X or 56F83XX Digital Signal Controller as the dedicated motor control device It can be adapted to NXP® 56F81XX Digital Signal Controllers The speed closed loop ACIM drive is implemented The system is targeted for applications in both industrial and appliance fields (e.g. washing machines, dishwashers, industrial drives, machine tools, variable speed drives, elevators etc.) Features Vector control technique used for ACIM control Targeted for 56F80X, 56F83XX, and 56F81XX Digital Signal Controllers Running on a 3-phase AC induction motor control development platform at variable line voltage 115/230V AC Encoder used for a speed calculation Control technique incorporates: Speed control loop with inner q axis stator current loop Rotor flux control loop with inner d axis stator current loop Field-weakening technique Stator phase currents measurement method DC-Bus ripple elimination Motor and generator mode DC-Bus brake Overvoltage, undervoltage, overcurrent and overheating fault protection FreeMASTER software control interface and monitor Block Diagram Board Design Resources

  Overview The USB Type-C allows multi-function signaling over the same connector. Our active cable application supports the connectivity of data, video, security, and power over a single connector. The active cables system for Type-C supports up to 10 Gbps. The MCU provides fundamental signal processing and management duties. It communicates with both the signal conditioner and USB PD PHY to organize signal traffic and power flow. Interactive Block Diagram Recommended Products Category Products MCU Kinetis® K Series: High-Performance Microcontrollers (MCUs) based on Arm® Cortex®-M4 Core | NXP    LPC800 Series: Low-Cost Microcontrollers (MCUs) based on Arm® Cortex®-M0+ Cores | NXP  Authentication A1006 | Secure Authenticator IC: Embedded Security Platform | NXP  Signal Conditioners SuperSpeed USB 3.0 redriver | NXP    PTN36043A: USB Type-C SuperSpeed active switch | NXP  USB PD PHY PTN5100 | NXP    PTN5100D | NXP    PTN5150 | NXP    Featured Videos Link NXP USB Type C | NXP  USB Type C Shield Board | NXP  NXP® End to End Secure USB Type-C Solution | NXP  Documentation Link Features Paving The Way for USB Type-C Connectors  Delivering data, video, security, and power in one small, easy-to-insert connector, the new USB Type-C connector. PTN5110N PD PHY application programming guide  PTN5110N is a 1-port TCPC (Type-C Port controller) compliant USB Power Delivery (PD) PHY IC   Training Link USB Type-C Overview - Part 1| Introduction to USB Type-C | NXP  Authentication for USB Type-C - Part 1 | Introduction to NXP Identification & Security | NXP  NXP USB Type-C Solution - Part 1| Overview of NXP Secure Interfaces & Power Solutions | NXP    Community Links Link Other NXP Products  Secure Authentication  Introduction to USB Type-C and Type-C Solutions from NXP  USB Type-C Overview  MHW-N1910 Authentication for USB Type-C 

  Overview The NXP ®  Smart Application Blueprint for Rapid Engineering (SABRE) series of market-focused reference designs delivers the SABRE platform for eReaders based on the i.MX508 processor. The i.MX508 is the first SoC designed specifically for eReaders with a high-performance Arm® Cortex®-A8 CPU and integrated display controller certified by E Ink® for Electronic Paper Display (EPD) panels The SABRE platform provides a reference design for EPD display, touch control, audio playback as well as the ability to add WLAN, 3G modem or Bluetooth® The platform was designed to facilitate software development with faster time to market through support of both Linux® and Android™ operating systems Archived content is no longer updated and is made available for historical reference only.   Features CPU Complex Up to 800 MHz Arm Cortex-A8 32 KB instruction and data caches Unified 256 KB L2 cache NEON SIMD media accelerator Vector floating point coprocessor Multimedia OpenVG™ 1.1 hardware accelerator 32-bit primary display support up to SXGA+ resolution 16-bit secondary display support EPD Controller supporting beyond 2048 × 1536 at 106 Hz refresh (or 4096 × 4096 at 20 Hz) Pixel Processing Pipeline (PxP) supporting CSC, Combine, Rotate, Gamma Mapping Display 6”Electronic Paper Display Panel daughter card powered by E-Ink External Memory Interface Up to 2 GB LP-DDR2, DDR2 and LP-DDR1(mDDR), 16/32-bit SLC/MLC NAND flash, 8/16-bit with 32-bit ECC Advanced Power Management Multiple independent power domains State Retention Power Gating (SRPG) Dynamic voltage and frequency scaling (DVFS) Connectivity High-Speed USB 2.0 OTG with PHY High-Speed USB 2.0 Host with PHY Controllers Wide array of serial interfaces, including SDIO, SPI, I2C and UART I2S audio interface 10/100 Ethernet controller   Design Resources  

Overview This reference design is based on 32-bit DSC MC56F84789, to demo a 3in1 Air-Conditioner Outdoor Unit. This reference design jump-starts your ability to leverage the NXP ®  DSCs' advanced feature sets via complete software, tools and hardware platform. High performance, low cost all DC VF air-conditioner outdoor unit control system Three control objectives (interleaved single-phase PFC converter, fan and compressor) with one MCU device Input voltage range of 85 – 265VAC/40 – 70H Single-phase two channels interleaved PFC converter compatible with global mains input, 99.9% power factor, 8% input current THDi Sensorless FOC algorithm for both compressor and fan Anti-typhoon startup for fan, and on-line load torque compensation control for compressor to reduce system vibration and noise Reliable startup performance under full load and input voltage range Extreme low/high speed (from 1Hz to 150Hz) performance with extended flux observer Over-/under-voltage, over-current, over-temperature, over-input power protection and lock of rotor detection FreeMASTER GUI for easy debugging Features MC56F84789 3in1 Air-Conditioner Outdoor Unit Block Diagram Board Design Resources

Overview Small high-speed BLDC motors have a very low inductance, which is different from conventional BLDC motors. When PWM control is applied to the phases of a small high-speed BLDC motor, the current follows the rectangular PWM voltage shape. This change of current magnetizes and demagnetizes the motor iron at a frequency equal to the PWM frequency, which can cause the motor to become hot enough to be damaged. To prevent this, special techniques are required to control this type of motor. The method used in this reference design consists of a DC/DC inverter that generates the desired voltage for the motor. The motor then uses a conventional 3-phase inverter for commutation. Features Voltage control of a BLDC motor using Hall sensors Targeted at the MC56F8013 Controller Board Running on "3-Phase Power Stage with DC/DC Inverter Lite" Control technique incorporating: BLDC motor closed-loop voltage control using a DC/DC inverter BLDC motor closed-loop speed control Both directions of rotation (however, because an impeller fan is used in the application, the FreeMASTER page is locked to one direction only) Both motor mode and generator mode Starting from any motor position without rotor alignment Minimum speed - 300 RPM Maximum speed - 38000 RPM FreeMASTER software control interface (motor start/stop, speed setup) FreeMASTER software monitor FreeMASTER software graphical control page (required speed, actual motor speed, start/stop status, DC bus voltage level, motor current, system status) FreeMASTER software speed scope (observes actual and desired speeds) FreeMASTER software Hall sensors scope (observes actual state of the Hall sensors) DC bus over- and under-voltage, over-current, and Hall sensor cable error fault protection Block Diagram Board Design Resources

Overview Human Fall Detection using 3-axis Accelerometer provides an implementation of human activity/fall detection mainly targeted for medical and security applications.This reference design is based on the 3-Axis accelerometer MMA7260Q, RF transceiver MC13192 and the Digital Signal Controller56F8013. The idea is to provide information that helps determine if a person has suffered an accident (if the person has fallen and to provide information related to the fall to determine the magnitude and characteristics of the accident. This application could result extremely useful to the police, firemen, and elderly people. Human Fall Detection using 3-axis Accelerometer is a modular architecture. The user is able to use Digital Signal Processing capability, wireless/serial communication interfaces, 3-axis sensing, external memory for data storage, plus the ability to reprogram the board with different applications with a JTAG interface. Archived content is no longer updated and is made available for historical reference only. Features Three-axis low g accelerometer (MMA7260Q). 2.4 GHz RF transceiver data modem for 802.15.4 applications (MC13192). Digital Signal Controller (56F8013). 9V Battery Operation, Serial communication Interface (RS-232),2 LED’s, 1 Buzzer and 2 Push-Buttons. The Hardware for the Parallel Port to JTAG/EOnCE adapter can be found at: AXIOM MAN and the hardware for the Parallel to JTAG/OnCE Interface providing low cost migration path from the DSP56F800DEMO board to your target hardware  at SEG13LLC. Design Resources

  Overview The Altimeter Barometer Reference Design is used for directly measuring the barometric pressure, determining altitude and making simple weather predictions. The barometer pressure readings are achieved using the compensated MPX2102A pressure sensor, a HCXX series of Flash microcontroller unit (MCU), and an LCD display. This reference design enables the user to evaluate a pressure sensor for barometer, personal weather station and altimeter applications. This design can be used for altimetry features in wrist watches, cell phones, GPS systems and other electronic devices. In addition, many systems require barometric pressure data to correct system response errors. This application note describes the reliability and accuracy that our sensors can provide in a barometer or altimeter system. Archived content is no longer updated and is made available for historical reference only.   Features Demonstrates barometric pressure and altitude Pressure Sensor: MPXM2102A MPAK Package Sensitivity: 0.4 mV / kPa Pressure Rating: 100kPa (Max) Microprocessor: MC68HC908QT4 4.0K Bytes of in-application reprogrammable Flash and 128 Bytes of RAM High performance, easy to use, HC08 CPU 4 Channel 8-bit analog to digital converter 8-pin DIP or SOIC packages       Design Resources

Overview This reference design is based on 32-bit DSC MC56F84789, to demo a micro-step stepper motor control solution. This reference design jump-starts your ability to leverage the NXP ®  DSCs' advanced feature sets via complete software, tools and hardware platform. Two phases four wires stepper motor Motor self-adaptive function, auto motor parameters identification and control system adjustment Rated peak current selection by switch, the maximum current is up to 8 A Speed ratio: 1 : 1000 with position and speed closed loop control Current PID regulator Micro-step resolution selection by switch, the maximum resolution is up to 25600 steps/rev The maximum speed is up to 3000RPM with loading capability Pulse command mode: single pulse plus direction control Maximum 1 MHz pulse command input Smooth filter function for pulse command, enabled by switch Stop with half rated current FreeMASTER software control interface and monitor Features MC56F84789 Micro-Step Stepper Motor Control MAPS-56F84000 EVK Board MAPS-MC-LV3PH Motor Control Power Stage Block Diagram Design Resources

Overview This NXP® reference design describes a High Intensity Discharge (HID) lamp leveling system with a LIN-bus interface. Stepper motor controller operating as a LIN-bus slave (LIN Stepper Controller). All functionality is provided by a general purpose LIN-bus IC MM908E625 and LIN Stepper software (HC08 software). The LIN Master consists of a master control board, based on an MC9S12DP256 CPU, and a personal computer with a graphical user interface (GUI), running in a master software environment. The LIN-bus Stepper Controller can be used for any kind of stepper motor control using the LIN-bus serial communication protocol. Features LIN bus Interface rev 1.2 Bus speed 19.2 kbps Slave IC without external crystal or resonator Slave node clock synchronization ±15% Each LIN slave controls one bi-phase bipolar stepper motor Motor phase current limitation up to 700 mA Supply voltage 12 V d.c. Stepper motor control with stepping acceleration and deceleration ramp Stepping frequency up to 2,500 Hz Slave parameter configuration via LIN-bus Slave LIN signal reconfiguration via LIN-bus Code written in C-language Block Diagram Board Design Resources

Overview This reference design exhibits the suitability and advantages of the NXP® 56F80x and 56F83XX Digital Signal Controllers (DSCs) for torque control applications using a 3-phase PMSM motor with an encoder position sensor. It can also be adapted to 56F81XX Digital Signal Controllers PM synchronous motors are popular in a wide application area The PM synchronous motor lacks a commutator and is, therefore, more reliable than the DC motor The PM synchronous motor also has advantages when compared to an AC induction motor Features Targeted 56F80X, 56F83XX, and 56F81XX Digital Signal Controllers Torque producing current component closed loop Vector current control with position feedback Encoder position feedback Overvoltage, undervoltage and overcurrent fault protection FreeMASTER display interface Manual interface Block Diagram Board

Overview This drive application allows vector control of an AC Induction Motor (ACIM) running in a closed-speed loop without a speed/position sensor at a low cost and serves as an example of AC induction vector control drive design using an NXP ®  56F8013 with Processor Expert ®  software support. ACIM is ideal for appliance and industrial applications This design uses sensorless FOC to control an ACIM using the 56F8013 device, which can accommodate the sensorless FOC algorithm The motor control system is flexible enough to implement complex motion protocols while it drives a variable load. The system illustrates the features of the 56F8013 in motor control Features General: The motor control algorithm employs Stator-Flux-Oriented Control (SFOC) Power stage switches are controlled by Space Vector Pulse Width Modulation (SVPWM) No position information devices or stator flux measurement are used, a sensorless speed method is employed The motor is capable of forward and reverse rotation and has a speed range from 50rpm to 3000rpm The user controls motion profiles, rotation direction, and speed. The RS-232 communication supports further R&D by enabling the easy tuning of control parameters The motor drive system is designed to create minimal acoustic noise Active power factor correction which reduces the negative effects of the load on the power grid in conducted noise and imaginary power Design is low cost General Benefits: Improved End System Performance Energy savings Quieter operation Improved EMI performance System Cost savings Enhanced Reliability Performance: Input voltage: 85 ~265VAC Input frequency: 45 ~65HZ Rating bus voltage: 350V Rating output power: 500W Switch frequency of PFC switch: 100KHZ Switch frequency of inverter: 10KHZ Power factor: >95% Efficiency: >90% Communications: RS232 port for communication with optoisolation Visual Interface: Multi-segment LED indicators Block Diagram Board Design Resources

Overview This reference design shows the simplicity of a soft modem design, how few resources of the processor it takes, and how well it performs on USA average lines. This design omits the standard telecommunications Codec, instead of using PWM for output and ADC for input. Since both peripherals are readily available on one 56F8300/100 series device, along with more processing power than required from the single core, the design is a true one-chip, one-core system that includes telecommunications ability with room for even more system functionality. Ideal for advanced motion control, home appliances, medical monitoring, fire and security systems, power management, smart relays, and POS terminals. Features Hybrid architecture facilitates implementation of V.21 and V.22bis modem, control, and signal processing functions in one chip Consumes only 7.5 MIPS for the modem function - Only 15K words of Flash for the complete modem application and test harness High-performance, secured Flash memory eliminates the need for external storage devices Extended temperature range allows for operation of non-volatile memory in harsh environments Flash memory emulation of EEPROM eliminates the need for external non-volatile memory 32-bit performance with 16-bit code density On-chip voltage regulator and power management reduces overall system cost Off-chip memory expansion capabilities allow for glueless interfacing with the additional memory of external devices, without sacrificing performance Boots directly from Flash, providing additional application flexibility High-performance PWM with programmable fault capability simplifies design and promotes compliance with safety regulations PWM and ADC modules are tightly coupled to reduce processing overhead; only one of each is used by the modem General purpose input/output (GPIO) pins support application-specific needs Simple in-application Flash memory programming via Enhanced OnCE or serial communication Block Diagram Board Design Resources

Overview The 56F8300 (56800E core) family of Digital Signal Controllers (DSCs) is well suited for UPS design, combining the DSP's calculation capability with MCU controller features on a single chip. Offers many dedicated peripherals, including Pulse Width Modulation (PWM) units, Analog-to-Digital Converters (ADC), timers, communication peripherals (SCI, SPI, CAN), on-board Flash and RAM Online Uninterruptible Power Supplies (OUPS) provides continuous power to the load during power outage or glitches caused by power source switching Ideal for computers, office equipment, communication systems and medical life support Features Single-device solution: Combines MCU functionality and DSP processing power TCP/IP network communication for remote control and monitoring Bidirectional AC/DC conversion High input power factor with Direct PFC and lower power pollution to the power grid Battery management to extend battery life and lower maintenance costs Power source and load conditioning can be monitored in real time TCP/IP network communication for remote control and monitoring Bypass operation during overload or service maintenance Expedites time-to-market using out-of-the-box software components Block Diagram Board Design Resources