NXP Low VCEsat (BISS) Transistors
NXP Low VCEsat (BISS) Transistors offer a dual load switch using double RETs and double BISS transistors. NXP Low VCEsat (BISS) Transistors keep power consumption and heat dissipation to a minimum, delivering low power consumption and high collector current capability by utilizing innovative mesh-emitter technology.
NXP PCF2129T Accurate Real Time Clock
NXP's PCF2129T Accurate Real Time Clock is a CMOS Real Time Clock (RTC) and calendar with an integrated Temperature Compensated Crystal (Xtal) Oscillator (TCXO) and a 32.768kHz quartz crystal optimized for very high accuracy and very low power consumption. The PCF2129T has a selectable I2C-bus or SPI-bus, a backup battery switch-over circuit, a programmable watchdog function, a timestamp function, and many other features. Typical applications include electronic metering, precision timekeeping, and GPS equipment.
NXP CBTL05023 Multiplexer/Demultiplexer Switch
NXP's CBTL05023 Multiplexer/Demultiplexer Switch is a multiplexer/demultiplexer switch chip for DisplayPort v1.2 signals and the control signals of a 10 Gbit/s channel. This high-speed MUX switch supports Thunderbolt™ I/O technology developed by Intel Corporation. Thunderbolt technology enables fast data transfers between PCs and peripheral and display devices by concurrently supporting data and display connections over a single cable. The 10 Gbit/s channel does not pass through this switch. This chip provides BIASOUT output control signal, and the DC-biasing pull-down resistors to facilitate an external 10 Gbit/s channel.
NXP LDMOS RF Power Transistors
NXP LDMOS RF Power Transistors are the dominant device technology used in high power RF amplifiers for frequencies ranging from 10 MHz to 3.8 GHz. They offer significant advantages over silicon bipolar transistors, such as very high ruggedness and efficiency, high gain, and compatibility with low cost packaging platforms. NXP's LDMOS devices deliver record performance up to 3.8 GHz and, for example, help wireless network operators realize best-in-class efficiencies for wireless base stations and hence reduce operating costs.
NXP JN516x Wireless Microcontrollers
NXP's JN516x Wireless Microcontroller series is a range of ultra low power, high performance wireless microcontrollers supporting JenNet-IP, ZigBee PRO or RF4CE networking stacks to facilitate the development of Home Automation, Smart Energy, Light Link and Remote control applications. They feature an enhanced 32-bit RISC processor with embedded Flash and EEPROM memory, offering high coding efficiency through variable width instructions, a multi-stage instruction pipeline and low power operation with programmable clock speeds. They also include a 2.4GHz IEEE 802.15.4 compliant transceiver and a comprehensive mix of analogue and digital peripherals. Three memory configurations are available to suit different applications. The best in class operating current of 15mA, with a 0.6uA sleep timer mode, gives excellent battery life allowing operation direct from a coin cell.
NXP I²C General Purpose I/O Expanders
NXP I²C General Purpose I/O Expanders provide GPIO expansion for most microprocessor families, allowing designers to save the GPIOs on microprocessors for other important functions. Designers can utilize the microprocessor GPIOs for important functions and use the I/O expander for other duties, including system monitoring, ACPI power switches, sensors, push buttons, LEDs, fans, and more. NXP GPIO expanders are ideal for adding fan and LED control to systems. They are also ideal for monitoring system functions and accepting push-button inputs.
Magneto-Resistive Angular Sensors
NXP's Magneto-Resistive Angular Sensors by using a true angular measurement, approach work accurately and reliably with no magnetic field strength variations. MR sensors operate virtually independent of magnet shifts and drifts due to lifetime, thermal influences or mechanical stress. They enable angular measurements with high accuracy by an excellent linearity and temperature drift behavior. NXP's magnetoresistive angle sensors offer clear advantages over devices employing other sensing methods. MR sensors give an output signal virtually independent of magnet tolerances, magnet temperature coefficients, magnet-sensor distance and positioning tolerances.
NXP LPC800 Cortex-M0+ 32-Bit MCUs and LPCXpresso Board
NXP LPC800 ARM Cortex™-M0+ 32-bit microcontrollers (MCUs) are available in low pin-count packages and offer easy-to-use peripherals addressing 8-bit application requirements while providing the 32-bit capabilities and exceptional power efficiency of the ARM® Cortex-M0 processor. Based on an ultra-low-power 30-MHz ARM Cortex-M0+ processor, LPC800 is fully compatible with the Cortex-M architecture and instruction set and offers superior code density to 8- / 16-bit architectures. The Cortex-M0+ features a two-stage pipeline that reduces power consumption while improving performance. LPC800 MCUs also take advantage of the Cortex-M0+ peripheral bus, allowing single-cycle access to the GPIOs. These features enable NXP LPC800 devices to offer deterministic, real-time performance – a key requirement for 8-bit developers. LPC800 includes game-changing features, such as a switch matrix that enables designers to assign on-chip peripherals to any pin with a single line of code or a single click in the configuration tool. LPC800 serial peripherals are designed to be as lean as possible, making them more responsive and efficient. The new SPI can operate as a slave at frequencies independent of the processor clock, solving the common frustration of having to over-sample 4-to-n times the SPI just to receive data. This decoupling of the SPI and processor clock speed reduces power and simplifies the system design. The I²C has also been re-engineered to allow the LPC800 to lie and wait at near-zero power consumption, even without a system clock, and wake up upon an address match.
NXP LPC800-Xpresso board provides a fast and easy way to develop applications using the LPC812 Cortex™-M0+ 32-bit microcontroller. NXP LPCXpresso™, the full-featured IDE-based software development tool, supports the complete product design cycle for the LPC800 family, easing the transition to 32-bit architectures.
NXP PCA9952/55 16-Channel Constant Current LED Drivers
NXP's PCA9952/55 16-Channel Constant Current LED Drivers are 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. Each LEDn output has its own 8-bit resolution (256 steps) fixed frequency individual PWM controller that operates at 31.25 kHz with a duty cycle that is adjustable from 0 % to 99.6 % to allow the LED to be set to a specific brightness value. An additional 8-bit resolution (256 steps) group PWM controller has both a fixed frequency of 122 Hz and an adjustable frequency between 15 Hz to once every 16.8 seconds with a duty cycle that is adjustable from 0 % to 99.6 % that is used to either dim or blink all LEDs with the same value.
NXP LPC4078 / LPC4088 Cortex™-M4 MCUs
NXP's LPC408x/7x ARM Cortex-M4 MCU is a digital signal controller for embedded applications requiring a high level of integration and low power dissipation. The ARM Cortex-M4 is a next generation core that offers system enhancements such as low power consumption, enhanced debug features, and a high level of support block integration. The LPC408x/7x adds a specialized flash memory accelerator to accomplish optimal performance when executing code from flash. The peripheral complement of the LPC408x/7x includes up to 512kB of flash program memory, up to 96kB of SRAM data memory, up to 4032 byte of EEPROM data memory, External Memory controller (EMC), LCD, Ethernet, USB Device/Host/OTG, an SPI Flash Interface (SPIFI), a General Purpose DMA controller, five UARTs, three SSP controllers, three I²C-bus interfaces, a Quadrature Encoder Interface, four general purpose timers, two general purpose PWMs with six outputs each and one motor control PWM, an ultra-low power RTC with separate battery supply and event recorder, a windowed watchdog timer, a CRC calculation engine and up to 165 general purpose I/O pins. The analog peripherals include one eight-channel 12-bit ADC, two analog comparators, and a DAC.
NXP SL3ICS1x02 Smart Label and Tag ICs
NXP's SL3ICS1x02 Smart Label and Tag ICs are dedicated chips for passive, intelligent tags and labels supporting the EPCglobal Class 1 Generation 2 UHF RFID standard. They are especially suited for applications where operating distances of several meters and high anti-collision rates are required. Its contact-less interface generates the power supply via the antenna circuit by propagative energy transmission from the interrogator (reader), while the system clock is generated by an on-chip oscillator. Data transmitted from interrogator to label/tag is demodulated by the interface, and it also modulates the interrogator’s electromagnetic field for data transmission from label/tag to interrogator.
NXP PCF2123 SPI Real Time Clock/Calendar
NXP's PCF2123 SPI Real Time Clock/Calendar is a CMOS Real-Time Clock
(RTC) and calendar optimized for low power applications. Data is
transferred serially via a Serial Peripheral Interface (SPI-bus) with a
maximum data rate of 6.25 Mbit/s. An alarm and timer function is also
available providing the possibility to generate a wake-up signal on an
interrupt pin. An offset register allows fine tuning of the clock.
Typical applications include time keeping, battery power devices,
metering, high duration timers, daily alarms, and low standby power
applications.
NXP PCF8523 Real-Time Clock (RTC) and Calendar
NXP's PCF8523 Real-Time Clock (RTC) and Calendar is a CMOS Real-Time Clock (RTC) and calendar optimized for low power consumption. Data is transferred serially via an I2C-bus with a maximum data rate of 1000 kbit/s. Alarm and timer functions are available with the possibility to generate a wake-up signal on an interrupt pin. An offset register allows fine-tuning of the clock. The PCF8523 has a backup battery switch-over circuit, which detects power failures and automatically switches to the battery supply when a power failure occurs.
NXP SSL2115x GreenChip™ Driver ICs
NXP SSL2115x GreenChip™ Driver ICs are high-efficiency devices designed for low-cost LED retrofit lamps. NXP SSL21151 and SSL21153 are ideal for non-dimmable 5W and 10W LED lamps, respectively, providing good current control in flyback and buck-boost configurations. SSL2115x devices enable small form-factor LED drivers, using primary-side sensing to regulate current and offering integrated LED open/short protections, an internal 700V MOSFET, and a circuit enabling start-up directly from the rectified AC voltage. With the use of an additional valley fill circuit, the SSL2115x series can offer a power factor of approximately 0.9.
NXP OM13014 LPCXpresso Board for LPC11U14
NXP OM13014 LPCXpresso™ Board for LPC11U14 is a low-cost development platform populated with the LPC11U14 to demonstrate the robust USB performance and other features of LPC11U1x Cortex™-M0 microcontrollers (MCUs). NXP LPCXpresso Board for LPC11U14 is composed of an LPCXpresso target board, LPC-Link, and IDE. LPCXpresso target boards include an integrated JTAG debugger and can connect to expansion boards to provide a variety of interfaces and I/O devices. The on-board JTAG debugger provides high-speed USB to JTAG/SWD interface to the IDE, and it can be connected to other debug targets such as a customer prototype. The LPC-Link is equipped with a 10-pin JTAG header, enabling seamless connection to a target via USB. LPCXpresso's IDE uses the standard GNU toolchain and optimized C library and can build an executable of any size with full code optimization.
NXP OM13043 DMX512/RDM Reference Design Board
NXP OM13043 DMX512/RDM Reference Design Board helps designers create DMX512-based systems for both communication and power stages. This NXP reference design provides a basic set of commands, including Remote Device Management, that can be used as a starting point to develop next-generation DMX512 platforms. NXP OM13043 DMX512 evaluation system features an NXP LPC1100XL Cortex-M0 series microcontroller that is uniquely suited to handle the communication requirements for intelligent lighting projects using DMX. The DMX512 system also includes a master controller board with the LPC11U00, a highly flexible Cortex-M0 USB MCU.
NXP OM13042 KNX Lighting Reference Design Board
NXP OM13042 KNX Lighting Reference Design Board features the NXP LPC1227 Cortex™-M0 microcontroller and ON Semiconductor's NCN5120 transceiver and is suitable for use in KNX twisted pair networks. NXP OM13042 KNX Lighting Reference Design Board is designed to simplify design process with a ready-to-implement, energy-efficient KNX twisted pair solution for applications such as lighting switches and control, HVA control, shutters, and occupancy detection. This KNX design board improves power efficiency, reduces development costs, and accelerates time to market for KNX applications on ARM Cortex-M0.
NXP OM13026 DALI NGX Reference Board
NXP OM13026 DALI NGX Reference Board allows designers to make a Digital Addressable Lighting Interface (DALI) network with ARM® 32-bit Cortex™-M0 microcontrollers. NXP OM13026 DALI Reference Board contains an isolated physical layer for the DALI bus with an LPC111x MCU for the DALI protocol handling, and many I/O functions to steer external lighting drivers for solid state or compact fluorescent lighting applications. Up to four PWM signals are available to independently drive different lighting units. Frequency and resolution of the signals is software programmable.
NXP SSL2109T GreenChip Controller
NXP SSL2109T GreenChip™ Controller is a high-efficiency buck controller for high-power, non-dimmable LED lighting applications using non-isolated topologies. NXP SSL2109T LED driver IC is designed for use with an external power switch and provides a single design platform for 100V, 120V, and 230V input voltages and power ranges up to 25W. SSL2109T provides LED retrofit lamp and driver module manufacturers with the flexibility to optimize external MOSFET selection based on cost, performance, and heat dissipation and across different power levels. SSL2109T is based on GreenChip technology and offers best-in-class efficiency up to 95% and a high level of integration.
NXP BGU Low-Noise Amplifier MMICs
NXP BGU Low-Noise Amplifier MMICs offer the best reception of weak GPS signals by suppressing strong cellular and WLAN transmit signals, an industry first. Linearity for these LNAs improves with a 10dB better IP3 under -40 to -20dBm jamming conditions, while NF remains below 1dB. By requiring only two external components, they save up to 50% in PCB size and 10% in component cost, offering the smallest footprint in the market.
NXP OM13031 Hitex LPC4350 Eval Board
NXP OM13031 Hitex LPC4350 Eval Board allows designers to quickly and easily evaluate the LPC4300 family of 32-bit microcontrollers (MCUs). NXP OM13031 Hitex LPC4350 Eval Board is equipped with 65MB SDRAM, 32MB parallel flash, 512kB SRAM, and a serial EEPROM, making it an ideal starting point for your next Cortex-M4 project. The board is populated with the LPC4350 MCU to demonstrate the LPC4300 family's features. LPC4350 offers industry leading dual-core performance, large internal memories, and advanced peripherals.
NXP HSDC-JAKIT1W2/DB High Speed Data Converter Board
NXP HSDC-JAKIT1W2/DB High Speed Data Converter Board is an ADC/DAC loop back demo based on Lattice Semiconductors ECP3 FPGA. NXP HSDC-JAKIT1W2/DB kit consists of high speed data converter boards. NXP DAC1408D650W2/DB is a 14bit dual channel, 2x, 4x and 8x interpolating DAC demonstration board equipped with JESD204A interface and suitable for dynamic performance evaluation from low to high output frequency signals sampling up to 650Msps. This demo board features the ECP3 FPGA and can be used for functional demonstration as well as JESD204A interoperability testing and verification between the DAC1408D650 and the ECP3 FPGA. NXP ADC1413D080W2/DB is a 14-bit dual channel ADC demonstration board equipped with on-board Lattice ECP3-70 FPGA and JESD204A interface. This demonstration board enables one channel ADC dynamic performance evaluation for analog input frequencies up to 30 MHz and sample clock frequencies from 65Msps to 80Msps.
NXP PCA9629 Fm+ I2C-Bus Stepper Motor Controller
NXP's PCA9629 Fm+ I2C-Bus Stepper Motor Controller is an I2C-bus controlled low-power CMOS device that provides all the logic and control required to drive a four phase stepper motor. PCA9629 is intended to be used with external high current drivers to drive the motor coils. Three stepper motor drive formats are supported: one-phase (wave drive), two-phase, and half-step. In addition, when used as inputs, four General Purpose Input/Outputs (GPIOs) allow sensing of logic level output from optical interrupter modules and generate active LOW interrupt signal on the INT pin of PCA9629. This is a useful feature in sensing home position of motor shaft or reference for step pulses. Upon interrupt, the PCA9629 can be programmed to automatically stop the motor or reverse the direction of rotation of motor.
NXP PCA9509 Level Translating I2C-Bus/SMBus Repeater
The NXP PCA9509A Level Translating I2C-Bus/SMBus Repeater has two voltage supplies that enables processor low voltage 2-wire serial bus to interface with standard I2C-bus or SMBus I/O. While retaining all the operating modes and features of the I2C-bus system during the level shifts, it also permits extension of the I2C-bus by providing bidirectional buffering for both the data (SDA) and the clock (SCL) lines, thus enabling the I2C-bus or SMBus maximum capacitance of 400 pF on the higher voltage side. Port A allows a voltage range from 0.8 V to 1.5 V and requires no external pull-up resistors due to the internal current source. Port B allows a voltage range from 2.3 V to 5.5 V and is overvoltage tolerant. Both port A and port B SDA and SCL pins are high-impedance when the PCA9509A is unpowered.
NXP PCF8885 Capacitive 8-Channel Proximity Switch
NXP's PCF8885 Capacitive 8-Channel Proximity Switch uses a patented (EDISEN) method to detect a change in capacitance on remote sensing plates. Changes in the static capacitances (as opposed to dynamic capacitance changes) are automatically compensated using continuous auto-calibration. Remote sensing plates (for example, conductive foils) can be connected to the IC1 using coaxial cable. The eight input channels operate independently of each other. There is also a built-in option for a matrix arrangement of the sensors: interrupt generation only when two channels are activated simultaneously, suppression of additional channel outputs when two channels are already active.
NXP Semiconductors PSMNxxx N-Channel MOSFETs - EXPANSION
NXP's PSMNxxx N-Channel MOSFETs have been expanded by adding additional drain current (ID), drain-source on-state resistance (RDS(on)), gate-drain charge (QGD), and total power dissipation (Ptot) ratings. All of these packages are qualified with a junction temperature up to 175ºC. They are designed and qualified for use in a wide range of industrial, communications, and domestic equipment. They are highly efficient due to low switching and conduction losses and are suitable for standard level gate drive sources. Some of these are optimized for 4.5V gate drive utilizing NextPower Superjunction technology and have ultra-low QG, QGD and QOSS for high system efficiencies at low and high loads. Typical applications for these devices include dc-to-dc converters, load switching, motor control, synchronous buck regulators, and server power supplies.
NXP Semiconductors PSMNxxx N-Channel MOSFETs include standard and logic level, regular and enhancement mode, N-Channel MOSFETs in LFPAK, I2PAK, TO-220, and DFN3333-8 packages qualified to 150°C or 175°C. These NXP Semiconductors PSMNxxx N-Channel MOSFETs are designed and qualified for use in a wide range of industrial, communications, and domestic equipment. The NXP logic level enhancement mode N-Channel MOSFETs in LFPAK packages feature ultra low QG, QGD, and QOSS for high system efficiencies at low and high loads, and ultra low RDSon and low parasitic inductance. They are also optimized for 4.5V gate drive utilising NextPower Superjunction technology. The NXP standard and logic level N-Channel MOSFETs in I2PAK and TO-220 packages feature high efficiency due to low switching and conduction losses and are suitable for standard or logic level gate drive sources.
View the entire PSMNxxx Series N-Channel MOSFETs
NXP Semiconductors LPC1115FBD48 Cortex™-M0 Microcontroller
NXP Semiconductors has expanded the LPC1100 ARM Cortex™-M0 Microcontroller Series to include the LPC1115FBD48 with 64kB of Flash memory and 8kB of data memory as well as unique API-driven power profiles that provide users with ready-to-use power management templates.
The NXP Semiconductors LPC11xx Series ARM Cortex™-M0 Microcontroller (MCU) is built around the smallest, lowest power, most energy-efficient ARM core ever developed. The NXP Semiconductors LPC11xx MCU is ideally equipped for use in battery-powered consumer devices, smart meters, motor control devices, and more. The NXP Semiconductors LPC11U24xx devices feature 50 MHz operation, nested vectored interrupt controller for fast deterministic interrupts, and a wakeup interrupt controller that allows automatic wake from any priority interrupt. LPC11xx ARM Cortex-M0 MCUs offer three reduced power modes: sleep, deep-sleep, and deep power-down.
View the entire LPC1100 ARM Cortex-M0 Series.
NXP PN544 NFC Controller
NXP's PN544 NFC Controller is a high-quality, high-performance NFC controller that enables a new range of contactless applications for improved on-the-go experiences. It complies with all released NFC and ETSI/SCP SWP and HCI standards, guarantees interoperability with the existing infrastructure, and provides a flexible, full-featured platform for meeting GSMA requirements in next-generation NFC-enabled devices and services. It offers fully host-controllable power states, delivers a small footprint, and supports multiple secure elements.
NXP Semiconductors PTN36241B USB 3.0 Re-Driver
NXP PTN36241B SuperSpeed USB 3.0 Re-Driver IC is a dual-channel device that enhances signal quality by performing receive equalization on the deteriorated input signal followed by transmit de-emphasis, maximizing system link performance. NXP PTN36241B USB 3.0 Re-Driver provides superior differential signal conditioning and enhancement capability. This allows the device to deliver significant flexibility and performance scaling for various systems with different PCB trace and cable channel conditions while still benefiting from optimum power consumption. NXP PTN36241B supports a data signaling rate of 5Gbps per channel with optional settings that provide a high level of extendability. This NXP USB 3.0 re-driver supports applications that require a greater level of configurability by delivering intelligent multiplexing of the I²C-bus interface with quinary (5-level) pins.
NXP PTN3392 2-Lane DisplayPort to VGA Adapter IC
NXP PTN3392 2-lane DisplayPort to VGA adapter IC is designed to connect a DisplayPort source to a VGA sink. NXP PTN3392 integrates a DisplayPort receiver and a high-speed triple video digital-to-analog converter that supports display resolutions from VGA to WUXGA. This NXP DisplayPort to VGA adapter IC supports either one or two DisplayPort v1.1a lanes operating at either 2.7Gbit/s or 1.62Gbit/s per lane. PTN3392 has "Flash-over-AUX" capability, enabling simple firmware upgradability in the field. PTN3392 is designed for single supply and minimizes application costs. This NXP device also aids in monitor detection by performing load sensing and reporting sink connection status to the source.
NXP Semiconductors OM13001 EA LPC1788 Developer's Kit
The NXP Semiconductors OM13001 EA LPC1788 Developer's Kit allows designers to get up and running quickly with the LPC1788 OEM Board. The NXP LPC1788 OEM Board is equipped with the NXP Cortex™-M3 LPC1788 microcontroller (MCU). The LPC1788 MCU is suitable for a wide range of applications that require advanced communication and high-quality graphic displays. The NXP OM13001 EA LPC1788 Developer's Kit includes the OEM Board, a base board, USB cable, and a headset with microphone.
NXP Semiconductors TDA5051A Modem IC and Demo Board Kit
NXP Semiconductors TDA5051A is a Power Line Modem IC dedicated to Amplitude Shift Keying (ASK) transmission by means of a home power line network at 600 baud or 1200 baud data rate. The NXP TDA5051A operates from a single 5V supply and enables easy connection to standard microcontrollers, including the NXP LPC11xx series. TDA5051A PLM IC employs control logic that provides full digital carrier generation and shaping and a high clock rate of 6-bit digital to analog converter that provides rejection of aliasing components. This NXP power line modem IC contains a fully integrated output power stage with overload protection. The receiver employs an AGC (Automatic Gain Control), 8-bit analog to digital converter and narrowband digital baseband filtering and digital demodulator. The modulation and demodulation frequency is set by clock source from microcontroller or on-chip crystal oscillator. The TDA5051A Power Line Modem Demo Board Kit provides quick and easy evaluation of this NXP PLM IC.
NXP Semiconductors LPC1778 / LPC1788 Cortex-M3 Microcontrollers
NXP Semiconductors LPC1778 and LPC1788 Cortex-M3 Microcontrollers are designed for embedded applications featuring a high level of integration and low power consumption at frequencies at 120MHz. NXP LPC1778 and LPC1788 MCUs feature 512kB of Flash memory, 96kB of data memory, Ethernet, USB 2.0 Host/OTG/Device, and an 8-channel DMA controller. These NXP Cortex-M3 MCUs also include an ultra-low power Real-Time Clock with separate battery supply and up to 165 general purpose I/O pins. LPC1778 and LPC1788 MCUs are ideal for use in eMetering, lighting, industrial networking, alarm systems, white goods, and motor control applications.
NXP Semiconductors LPC11C22 / LPC11C24 Cortex-M0 Microcontrollers
NXP Semiconductors LPC11C22 and LPC11C24 Cortex-M0 Microcontrollers are designed for 8-/16-bit microcontroller applications, offering high performance, low power, simple instruction set, and memory addressing together with reduced code size compared to existing 8-/16-bit architectures. These NXP Cortex-M0 MCUs include 16kB (LPC11C22) or 32kB (LPC11C24) of Flash memory, 8kB of data memory, one C_CAN controller, one Fast-mode Plus I²C-bus interface, one RS-485/EIA-485 UART, two SPI interfaces with SSP features, four general purpose counter/timers, a 10-bit ADC, and 36 general purpose I/O pins. On-chip C_CAN drivers and Flash In-System Programming tools via C_CAN are included. The LPC11C22 and LPC11C24 also feature an integrated on-chip, high-speed CAN transceiver. NXP LPC11C22 and LPC11C24 MCUs are ideal for use in a variety of applications, including eMetering, elevator systems, industrial and sensor-based networks, and white goods.
NXP LPC1100 ARM Cortex™-M0 32-bit MCUs - EXPANSION
NXP Semiconductors has expanded the LPC1100 ARM Cortex™-M0 Series to include USB capability.
Learn more.
The NXP Semiconductors LPC11xx Series ARM Cortex™-M0 Microcontroller (MCU) is built around the smallest, lowest power, most energy-efficient ARM core ever developed. The NXP Semiconductors LPC11xx MCU is ideally equipped for use in battery-powered consumer devices, smart meters, motor control devices, and more. The NXP Semiconductors LPC11U24xx devices feature 50 MHz operation, nested vectored interrupt controller for fast deterministic interrupts, and a wakeup interrupt controller that allows automatic wake from any priority interrupt. LPC11xx ARM Cortex-M0 MCUs offer three reduced power modes: sleep, deep-sleep, and deep power-down.
View the entire LPC1100 ARM Cortex™-M0 Series.