The document describes the LPC microcontroller portfolio from NXP, which includes over 400 32-bit microcontrollers ranging from entry-level to high-end designs that run Linux. It provides details on the LPC800, LPC1100, and other series, outlining the memory, peripherals, and features of representative models. The LPC devices offer power, performance and features for 8-, 16- and 32-bit applications, and provide complete solutions from a single vendor.
The log captures SNMP permission errors when a user attempts to access the system before being added. The user "netapp" is then added, resolving the issue. Network interfaces and storage disks are listed.
The document provides an overview of the MSP430 microcontroller family from Texas Instruments, focusing on the MSP430G2xx series and the MSP430G2553 model. Key points:
- The MSP430 is a 16-bit microcontroller designed for low power consumption in embedded applications.
- The MSP430G2xx series features flash-based ultra-low power MCUs from 0.5-56KB flash and 128B-4KB RAM.
- The MSP430G2553 has 512B RAM, 16KB flash, and supports frequencies up to 16MHz with various power saving modes down to 0.1uA current consumption.
This document provides information about the PIC16F8X family of microcontrollers. It includes the PIC16F83, PIC16F84, PIC16CR83, and PIC16CR84 devices. The document discusses features like memory organization, I/O ports, timers, EEPROM memory, instruction set, and electrical characteristics. It is intended to help engineers select and use these microcontrollers in applications such as motor control, sensors, locks, and other embedded systems.
This document provides information about the PIC16F8X family of microcontrollers. It includes the PIC16F83, PIC16F84, PIC16CR83, and PIC16CR84 devices. The document discusses features like memory organization, I/O ports, timers, EEPROM memory, instruction set, and electrical characteristics. It is intended to help engineers select and use these microcontrollers in applications such as motor control, sensors, locks, and other embedded systems.
The document describes the PIC16F8X family of microcontrollers. Key features include:
- Flash/EEPROM programmable memory up to 1K words
- Up to 68 bytes of RAM and 64 bytes of EEPROM data memory
- RISC CPU architecture with 35 instructions and 8-level deep stack
- 13 I/O pins with individual direction control
- Timers, interrupts, watchdog timer, low-power sleep mode
- In-circuit serial programming capability for reprogramming firmware
This document lists integrated circuits by number, including their code, packaging, number of pins, and observations. It includes microcontrollers, memory chips, programmable logic devices, serial EEPROMs, amplifiers, and other common ICs. The list is from G.M. Electronica S.A. located in Buenos Aires, Argentina and provides component information for engineers and hobbyists.
This document contains lecture notes for an introduction to the MSP430 microcontroller family from Texas Instruments. It discusses the MSP430 architecture including the CPU, registers, instruction set, memory organization, peripherals and provides examples of MSP430-based systems. It also describes how to get started with the EasyWeb2 development board for the MSP430 using a simple code example to blink an LED by toggling a port pin.
The document discusses the ARM7TDMI-S processor used in the LPC2148 microcontroller. It has a 32-bit ARM instruction set and a 16-bit THUMB instruction set. The LPC2148 has 32-512kB of onboard flash memory that can be programmed through various interfaces and has a minimum 100,000 erase/write cycles. It uses a crystal oscillator between 1-50MHz as its clock source and has two PLL modules, one to generate the system clock CCLK and one to supply the fixed 48MHz USB clock.
The log captures SNMP permission errors when a user attempts to access the system before being added. The user "netapp" is then added, resolving the issue. Network interfaces and storage disks are listed.
The document provides an overview of the MSP430 microcontroller family from Texas Instruments, focusing on the MSP430G2xx series and the MSP430G2553 model. Key points:
- The MSP430 is a 16-bit microcontroller designed for low power consumption in embedded applications.
- The MSP430G2xx series features flash-based ultra-low power MCUs from 0.5-56KB flash and 128B-4KB RAM.
- The MSP430G2553 has 512B RAM, 16KB flash, and supports frequencies up to 16MHz with various power saving modes down to 0.1uA current consumption.
This document provides information about the PIC16F8X family of microcontrollers. It includes the PIC16F83, PIC16F84, PIC16CR83, and PIC16CR84 devices. The document discusses features like memory organization, I/O ports, timers, EEPROM memory, instruction set, and electrical characteristics. It is intended to help engineers select and use these microcontrollers in applications such as motor control, sensors, locks, and other embedded systems.
This document provides information about the PIC16F8X family of microcontrollers. It includes the PIC16F83, PIC16F84, PIC16CR83, and PIC16CR84 devices. The document discusses features like memory organization, I/O ports, timers, EEPROM memory, instruction set, and electrical characteristics. It is intended to help engineers select and use these microcontrollers in applications such as motor control, sensors, locks, and other embedded systems.
The document describes the PIC16F8X family of microcontrollers. Key features include:
- Flash/EEPROM programmable memory up to 1K words
- Up to 68 bytes of RAM and 64 bytes of EEPROM data memory
- RISC CPU architecture with 35 instructions and 8-level deep stack
- 13 I/O pins with individual direction control
- Timers, interrupts, watchdog timer, low-power sleep mode
- In-circuit serial programming capability for reprogramming firmware
This document lists integrated circuits by number, including their code, packaging, number of pins, and observations. It includes microcontrollers, memory chips, programmable logic devices, serial EEPROMs, amplifiers, and other common ICs. The list is from G.M. Electronica S.A. located in Buenos Aires, Argentina and provides component information for engineers and hobbyists.
This document contains lecture notes for an introduction to the MSP430 microcontroller family from Texas Instruments. It discusses the MSP430 architecture including the CPU, registers, instruction set, memory organization, peripherals and provides examples of MSP430-based systems. It also describes how to get started with the EasyWeb2 development board for the MSP430 using a simple code example to blink an LED by toggling a port pin.
The document discusses the ARM7TDMI-S processor used in the LPC2148 microcontroller. It has a 32-bit ARM instruction set and a 16-bit THUMB instruction set. The LPC2148 has 32-512kB of onboard flash memory that can be programmed through various interfaces and has a minimum 100,000 erase/write cycles. It uses a crystal oscillator between 1-50MHz as its clock source and has two PLL modules, one to generate the system clock CCLK and one to supply the fixed 48MHz USB clock.
The document discusses the MSP430 microcontroller family from Texas Instruments. It provides an overview of the MSP430 architecture including its ultra-low power capabilities, peripherals, and development tools. Specific MSP430 derivatives and their features are also highlighted.
This document provides specifications for the Mini-ACE Mark3, a small integrated circuit that supports the MIL-STD-1553 and STANAG 3838 protocols. Key features include being powered entirely by 3.3 volts, small package size of 0.88 inches square, support for dual transceivers, and internal memory options of 4K or 64K words. It can operate as a bus controller, remote terminal, or message monitor and provides flexibility in host interfaces and data buffering options.
This document provides instructions for restoring an APC device's SPI EEPROM using an external programmer like the FlashcatUSB. It involves:
1. Preparing the FlashcatUSB programmer and downloading necessary files from APC and Microsoft websites.
2. Connecting the FlashcatUSB to the APC and running FlashcatUSB software to write the firmware BIN file to the APC's SPI EEPROM.
3. Reinstalling the system firmware from a microSD card and resetting the LAN MAC address using a console cable connected to the APC's debug port.
This document provides an overview of the FP-X PLC system from Panasonic, including its control units, expansion units, add-on cassettes, and FP0 expansion units. The FP-X control units offer high-speed processing, large program capacity, and expandability. Expansion is enabled through add-on cassettes that add functions and I/O, and through FP0 expansion units that connect via an adapter and support a wide range of specialized I/O types. The FP-X is designed to meet a variety of automation requirements with flexible configuration options.
This document provides an overview of the features and specifications of the ATmega164P/324P/644P microcontrollers. Key points include:
- It is an 8-bit AVR microcontroller with 16/32/64KB of flash memory, 512B/1KB/2KB of EEPROM, and 1KB/2KB/4KB of SRAM.
- It has an advanced RISC architecture with 131 powerful instructions that typically execute in a single clock cycle.
- It includes various peripherals like timers, PWM, ADC, USART, SPI and JTAG interface.
- It has 32 general purpose I/O lines and 32 general purpose working registers.
The LPC2148 microcontroller features a 32-bit ARM7TDMI-S CPU, 32-512KB of onboard flash memory, and 8-40KB of static RAM. It operates at speeds up to 60MHz and includes interfaces such as USB 2.0, UARTs, I2C, SPI, and timers. Its small size and low power consumption make it well-suited for applications requiring miniaturization like access control and point-of-sale devices.
The ATmega16 is a low-power CMOS 8-bit microcontroller based on the AVR enhanced
RISC architecture. By executing powerful instructions in a single clock cycle, the
ATmega16 achieves throughputs approaching 1 MIPS per MHz allowing the system
designer to optimize power consumption versus processing speed.
The document discusses microcontrollers and the MSP430 microcontroller. It begins by defining a microcontroller and comparing it to a microprocessor. It then describes the different types of microcontrollers and provides examples of their uses. The remainder of the document focuses specifically on the MSP430 microcontroller from Texas Instruments, describing its features such as low power consumption, peripherals, memory architecture, and clock system. It also discusses the MSP430's assembly language and interrupt handling capabilities.
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This document provides information about the memory mapping of the LPC111x/LPC11C1x microcontroller family, including:
- The flash and SRAM configurations for different parts in the family.
- An overview of the memory map, showing the flash, SRAM, and peripheral address spaces.
- Details on how the AHB and APB peripheral areas are divided to support multiple peripherals.
The TramelBlaze Chip Specification document describes a system-on-chip (SOC) featuring a 16-bit processor, universal asynchronous receiver/transmitter (UART), and 8 pulse-width modulation (PWM) blocks. The SOC is designed to provide simple embedded control and includes blocks for the processor, UART, PWM controller, and reset synchronization. Verification confirmed basic UART transmission and PWM functionality as specified.
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The document is a datasheet for the PIC16F84 microcontroller. It provides details about the microcontroller's
architecture, memory organization, I/O ports, timer module, data EEPROM, instruction set, electrical
characteristics, and development support. Specifically, it describes the PIC16F84's Harvard architecture with
separate program and data buses, 512 bytes of Flash program memory, 68 bytes of RAM, 64 bytes of EEPROM,
and a single 8-bit timer/counter module. It also lists the microcontroller's operating voltage, package options,
programming and development support tools available from Microchip.
The document provides information on the features and specifications of the ATmega8535 microcontroller, which includes an 8-bit AVR CPU, 8K bytes of flash memory, 512 bytes of EEPROM, 512 bytes of SRAM, 32 general purpose I/O lines, timers, serial interfaces, analog to digital converter, and six power saving modes. It also summarizes the pin configurations and functions of the microcontroller.
The document describes the features of the ATmega8535 microcontroller, which includes an 8-bit AVR processor, 8K bytes of flash memory, 512 bytes of EEPROM, 512 bytes of SRAM, various timers and peripherals, and low-power sleep modes. It operates from 2.7-5.5V and has up to 16 MHz clock speed. The microcontroller has extensive I/O capabilities with 32 programmable pins that can serve various purposes including analog inputs, serial communication, and more.
UplinQ - smart terrain™ feature for depth sensing camerasSatya Harish
Smart Terrain is a feature of the Qualcomm Vuforia SDK that allows devices with depth sensing cameras to reconstruct environments and interact with objects and surfaces. It provides advantages over standard cameras like automatic initialization and faster, richer results without requiring motion. Smart Terrain uses infrared depth sensors to project infrared light, fuse the RGB image with a depth map, and reconstruct surfaces and objects in the environment. Developers can utilize the Smart Terrain API for consistent lifecycle management and event handling across depth sensing devices.
SFD, a French telecommunications solutions distributor, implemented HP Service Anywhere to modernize their aging IT asset management and service desk software. The cloud-based SaaS solution automated problem ticketing, increased productivity, improved service levels, and reduced costs. It lowered SFD's dropped call rate from 32% to 3% through powerful computer telephony integration. The flexible SaaS model also generated significant savings by eliminating hardware purchases and providing faster upgrades.
Lte mtc - optimizing lte advanced for machine-type communicationsSatya Harish
LTE MTC optimizes LTE Advanced to better support machine-to-machine communications by increasing battery life, reducing device complexity, and enhancing coverage while co-existing with existing mobile broadband services. These optimizations are part of the upcoming Release 13 of the 3GPP standard and will benefit the growing market of connected devices and machines.
BOOK - IBM Implementing ibm system directory 6.1Satya Harish
This document provides an overview and guide to implementing IBM Systems Director 6.1. It discusses the key features and components of IBM Systems Director 6.1. It also covers planning considerations for hardware, software, security and other aspects. The document aims to help readers get the most out of IBM Systems Director 6.1 through practical implementation guidance and real-world scenarios.
HP Case study performancetestingusinghp-loadrunnerSatya Harish
AdactIn was hired to perform performance testing on an education sector client's student enrollment application that was upgrading its Oracle database from 10g to 11g. AdactIn developed performance test scripts using LoadRunner 11.50 to test the enrollment, withdrawal, and transfer processes. The testing identified issues like missing indexes, slow queries, and memory usage that were addressed. When re-executed, the scripts showed a significant improvement in transaction response times after implementing the recommended fixes. The client was able to successfully upgrade its database with no performance impacts.
This document is an acknowledgement and about the author section from a book on Visual Basic 6.0 Made Easy. The author thanks his family for their contributions to editing and writing parts of the book. He also thanks visitors to his Visual Basic tutorial website for their support. The author holds degrees in mathematics, management, and business administration, and has been programming for over 15 years. He created a popular online Visual Basic tutorial in 1996 that receives millions of visitors.
Small and midsize banks seek new ways to attract and retain customers and compete with larger banks that have more resources for analytics. Fiserv helps these banks by turning billions of transactions into actionable insights using IBM technology. This enables targeted marketing that can increase response rates by 100% and savings of an estimated $8 million over five years through server consolidation and virtualization.
The document discusses the MSP430 microcontroller family from Texas Instruments. It provides an overview of the MSP430 architecture including its ultra-low power capabilities, peripherals, and development tools. Specific MSP430 derivatives and their features are also highlighted.
This document provides specifications for the Mini-ACE Mark3, a small integrated circuit that supports the MIL-STD-1553 and STANAG 3838 protocols. Key features include being powered entirely by 3.3 volts, small package size of 0.88 inches square, support for dual transceivers, and internal memory options of 4K or 64K words. It can operate as a bus controller, remote terminal, or message monitor and provides flexibility in host interfaces and data buffering options.
This document provides instructions for restoring an APC device's SPI EEPROM using an external programmer like the FlashcatUSB. It involves:
1. Preparing the FlashcatUSB programmer and downloading necessary files from APC and Microsoft websites.
2. Connecting the FlashcatUSB to the APC and running FlashcatUSB software to write the firmware BIN file to the APC's SPI EEPROM.
3. Reinstalling the system firmware from a microSD card and resetting the LAN MAC address using a console cable connected to the APC's debug port.
This document provides an overview of the FP-X PLC system from Panasonic, including its control units, expansion units, add-on cassettes, and FP0 expansion units. The FP-X control units offer high-speed processing, large program capacity, and expandability. Expansion is enabled through add-on cassettes that add functions and I/O, and through FP0 expansion units that connect via an adapter and support a wide range of specialized I/O types. The FP-X is designed to meet a variety of automation requirements with flexible configuration options.
This document provides an overview of the features and specifications of the ATmega164P/324P/644P microcontrollers. Key points include:
- It is an 8-bit AVR microcontroller with 16/32/64KB of flash memory, 512B/1KB/2KB of EEPROM, and 1KB/2KB/4KB of SRAM.
- It has an advanced RISC architecture with 131 powerful instructions that typically execute in a single clock cycle.
- It includes various peripherals like timers, PWM, ADC, USART, SPI and JTAG interface.
- It has 32 general purpose I/O lines and 32 general purpose working registers.
The LPC2148 microcontroller features a 32-bit ARM7TDMI-S CPU, 32-512KB of onboard flash memory, and 8-40KB of static RAM. It operates at speeds up to 60MHz and includes interfaces such as USB 2.0, UARTs, I2C, SPI, and timers. Its small size and low power consumption make it well-suited for applications requiring miniaturization like access control and point-of-sale devices.
The ATmega16 is a low-power CMOS 8-bit microcontroller based on the AVR enhanced
RISC architecture. By executing powerful instructions in a single clock cycle, the
ATmega16 achieves throughputs approaching 1 MIPS per MHz allowing the system
designer to optimize power consumption versus processing speed.
The document discusses microcontrollers and the MSP430 microcontroller. It begins by defining a microcontroller and comparing it to a microprocessor. It then describes the different types of microcontrollers and provides examples of their uses. The remainder of the document focuses specifically on the MSP430 microcontroller from Texas Instruments, describing its features such as low power consumption, peripherals, memory architecture, and clock system. It also discusses the MSP430's assembly language and interrupt handling capabilities.
American Fibertek MX46FXSCPOE Data SheetJMAC Supply
Buy the American Fibertek MX46FXSCPOE at JMAC Supply.
https://www.jmac.com/American_Fibertek_MX46FXSCPOE_p/american-fibertek-mx46fxscpoe.htm?=slideshare
This document provides information about the memory mapping of the LPC111x/LPC11C1x microcontroller family, including:
- The flash and SRAM configurations for different parts in the family.
- An overview of the memory map, showing the flash, SRAM, and peripheral address spaces.
- Details on how the AHB and APB peripheral areas are divided to support multiple peripherals.
The TramelBlaze Chip Specification document describes a system-on-chip (SOC) featuring a 16-bit processor, universal asynchronous receiver/transmitter (UART), and 8 pulse-width modulation (PWM) blocks. The SOC is designed to provide simple embedded control and includes blocks for the processor, UART, PWM controller, and reset synchronization. Verification confirmed basic UART transmission and PWM functionality as specified.
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The document is a datasheet for the PIC16F84 microcontroller. It provides details about the microcontroller's
architecture, memory organization, I/O ports, timer module, data EEPROM, instruction set, electrical
characteristics, and development support. Specifically, it describes the PIC16F84's Harvard architecture with
separate program and data buses, 512 bytes of Flash program memory, 68 bytes of RAM, 64 bytes of EEPROM,
and a single 8-bit timer/counter module. It also lists the microcontroller's operating voltage, package options,
programming and development support tools available from Microchip.
The document provides information on the features and specifications of the ATmega8535 microcontroller, which includes an 8-bit AVR CPU, 8K bytes of flash memory, 512 bytes of EEPROM, 512 bytes of SRAM, 32 general purpose I/O lines, timers, serial interfaces, analog to digital converter, and six power saving modes. It also summarizes the pin configurations and functions of the microcontroller.
The document describes the features of the ATmega8535 microcontroller, which includes an 8-bit AVR processor, 8K bytes of flash memory, 512 bytes of EEPROM, 512 bytes of SRAM, various timers and peripherals, and low-power sleep modes. It operates from 2.7-5.5V and has up to 16 MHz clock speed. The microcontroller has extensive I/O capabilities with 32 programmable pins that can serve various purposes including analog inputs, serial communication, and more.
UplinQ - smart terrain™ feature for depth sensing camerasSatya Harish
Smart Terrain is a feature of the Qualcomm Vuforia SDK that allows devices with depth sensing cameras to reconstruct environments and interact with objects and surfaces. It provides advantages over standard cameras like automatic initialization and faster, richer results without requiring motion. Smart Terrain uses infrared depth sensors to project infrared light, fuse the RGB image with a depth map, and reconstruct surfaces and objects in the environment. Developers can utilize the Smart Terrain API for consistent lifecycle management and event handling across depth sensing devices.
SFD, a French telecommunications solutions distributor, implemented HP Service Anywhere to modernize their aging IT asset management and service desk software. The cloud-based SaaS solution automated problem ticketing, increased productivity, improved service levels, and reduced costs. It lowered SFD's dropped call rate from 32% to 3% through powerful computer telephony integration. The flexible SaaS model also generated significant savings by eliminating hardware purchases and providing faster upgrades.
Lte mtc - optimizing lte advanced for machine-type communicationsSatya Harish
LTE MTC optimizes LTE Advanced to better support machine-to-machine communications by increasing battery life, reducing device complexity, and enhancing coverage while co-existing with existing mobile broadband services. These optimizations are part of the upcoming Release 13 of the 3GPP standard and will benefit the growing market of connected devices and machines.
BOOK - IBM Implementing ibm system directory 6.1Satya Harish
This document provides an overview and guide to implementing IBM Systems Director 6.1. It discusses the key features and components of IBM Systems Director 6.1. It also covers planning considerations for hardware, software, security and other aspects. The document aims to help readers get the most out of IBM Systems Director 6.1 through practical implementation guidance and real-world scenarios.
HP Case study performancetestingusinghp-loadrunnerSatya Harish
AdactIn was hired to perform performance testing on an education sector client's student enrollment application that was upgrading its Oracle database from 10g to 11g. AdactIn developed performance test scripts using LoadRunner 11.50 to test the enrollment, withdrawal, and transfer processes. The testing identified issues like missing indexes, slow queries, and memory usage that were addressed. When re-executed, the scripts showed a significant improvement in transaction response times after implementing the recommended fixes. The client was able to successfully upgrade its database with no performance impacts.
This document is an acknowledgement and about the author section from a book on Visual Basic 6.0 Made Easy. The author thanks his family for their contributions to editing and writing parts of the book. He also thanks visitors to his Visual Basic tutorial website for their support. The author holds degrees in mathematics, management, and business administration, and has been programming for over 15 years. He created a popular online Visual Basic tutorial in 1996 that receives millions of visitors.
Small and midsize banks seek new ways to attract and retain customers and compete with larger banks that have more resources for analytics. Fiserv helps these banks by turning billions of transactions into actionable insights using IBM technology. This enables targeted marketing that can increase response rates by 100% and savings of an estimated $8 million over five years through server consolidation and virtualization.
This document provides an introduction and overview of SQL (Structured Query Language). It defines SQL as a standard language for managing and accessing relational database management systems (RDBMS). It describes some key SQL commands like SELECT, UPDATE, DELETE, and INSERT. It also notes that while SQL is a standard, different database systems may have their own proprietary extensions. The document uses examples from the Northwind sample database to demonstrate basic SQL statements and clauses.
G07.2014 magic quadrant for enterprise file synchronization and sharingSatya Harish
Gartner's Magic Quadrant report evaluated vendors in the enterprise file synchronization and sharing (EFSS) market. EMC Syncplicity was named a leader in this market. The report provides qualitative analysis of the EFSS market, including where it is going. It also analyzes key EFSS participants. Gartner does not endorse any particular vendor but provides the report to help technology users understand the options in this space.
The document provides an overview and analysis of application delivery controllers (ADCs) and the ADC market. It discusses key ADC vendors including their strengths, cautions, and positioning in the market. The Magic Quadrant graphic evaluates vendors based on completeness of vision and ability to execute. F5 remains the market leader while Citrix, A10 Networks, Radware, and Brocade are also leaders.
This document provides a summary of Gartner's Magic Quadrant report on enterprise content management vendors. It assesses 22 vendors and places them in four categories based on their completeness of vision and ability to execute. The summary analyzes the strengths and cautions of several leading vendors, including Alfresco, EMC, Ever Team, Fabasoft, HP, Hyland, and IBM. It describes their product portfolios, target markets, growth strategies, and areas for improvement.
This document discusses the need for standards in 3D design and manufacturing to facilitate the integration of die from multiple sources and mitigate risks. It proposes leveraging existing standards bodies and industry forums to develop standards in several key areas, including design exchange formats, modeling parameters, bump layout specifications, and metrology and reliability metrics. The document recommends convening expert groups to define a complete list of required design information exchange formats and to propose and champion specific format standards.
The document describes the PIC16F8X family of microcontrollers, which includes the PIC16F83, PIC16F84, PIC16CR83, and PIC16CR84. It has features like a RISC CPU, programmable I/O pins, timer module, data EEPROM memory, and special features like low power modes, watchdog timer, and in-circuit serial programming. The PIC16F8X is suitable for applications ranging from motor control to security devices due to its small size, low power usage, and reprogrammable Flash memory.
This document provides information on the PIC16F8X family of microcontrollers, including the PIC16F83, PIC16F84, PIC16CR83, and PIC16CR84 models. It describes the key features of these devices such as their RISC CPU architecture, memory organization including flash program memory and EEPROM data memory, I/O ports, timer functions, and special features including in-circuit serial programming and low power sleep mode. Application areas mentioned include automotive, appliance, sensor, security, and smart card uses.
Technology is constantly changing. New microcontrollers become available every year. The one thing that has stayed the same is the C programming language used to program these microcontrollers. If you would like to learn this standard language to program microcontrollers, then this book is for you!
Arduino is the hardware platform used to teach the C programming language as Arduino boards are available worldwide and contain the popular AVR microcontrollers from Atmel.
This document provides an overview of Renesas' H8S microcontroller family, including key features of popular series like the H8S/2100, H8S/2200, H8S/2300 and H8S/2600. It describes typical applications for H8S devices and gives brief details about each sub-series, highlighting aspects like operating speed, memory size, interfaces and packaging. Additional resources are provided for ordering parts and getting technical support.
This document provides an overview and specifications for the Atmel AVR XMEGA D4 microcontroller family. It includes descriptions of the microcontroller's features such as flash memory size, SRAM, peripherals, operating voltage and frequency ranges, and packaging options. Typical applications for these microcontrollers are also listed.
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The document discusses the design of a portable blood pressure monitor system using a Freescale MCF51QE128 microcontroller. It outlines the system architecture including components like a pressure sensor, LCD display, and battery management. Evaluation boards, peripherals, and additional resources for designing such a system are also presented.
This document introduces the RS08 family of microcontrollers from Freescale. It provides an overview of the RS08 core architecture including new instructions and addressing modes for code size optimization. It describes the target applications for these ultra-low-end MCUs such as lighting controls and small handheld devices. Block diagrams are shown for the RS08LA, RS08LE, and RS08KB MCU families. Development tools including demo boards and a background debug mode are also outlined. Additional resources for ordering parts and getting technical support are provided.
This document is a user manual for the LPC214x microcontrollers. It provides an overview of the microcontrollers' features, applications, device information, architectural overview, and memory maps. Key features include an ARM7 CPU, on-chip flash memory ranging from 32kB to 512kB, SRAM from 8kB to 40kB, and peripherals such as USB, ADC, DAC, timers, and GPIO. The manual is intended to help users understand and utilize the microcontrollers.
This document lists integrated circuits by number, including their code, packaging, number of pins, and observations. It includes microcontrollers, memory chips, programmable logic devices, serial EEPROMs, amplifiers, and other common ICs. The list is from G.M. Electronica S.A. located in Buenos Aires, Argentina and provides component information for engineers and hobbyists.
The document lists and provides details on many early processors from Intel and other manufacturers in chronological order. It begins with the 4-bit Intel 4004 microprocessor from 1971 and discusses the related MCS-4 family. It then covers the early 8-bit processors like the 8008 and 8080, and later 8-bit processors like the 8085. The document also summarizes Intel's early microcontroller lines like the MCS-48 family based on the 8048 and the MCS-51 family based on the 8051. It concludes by briefly mentioning the 16-bit Intel 8086 processor and some of its variants like the 8088 and 80186.
The document provides information about various 8-bit microcontrollers including the 8051, PIC, and AVR families. It discusses the original 8051 microcontroller released by Intel in 1981 and its features. It then summarizes the different members of the 8051 family and versions produced by other manufacturers like Atmel. The document also summarizes the different series within the PIC family from Microchip including the baseline, mid-range, enhanced mid-range, and PIC18 architectures. Finally, it discusses the AVR architecture from Atmel and provides details on the tinyAVR, megaAVR, and XmegaAVR families.
This document describes the features of the Atmel ATmega169P 8-bit microcontroller. It has 16KB of in-system programmable flash memory, 512B of EEPROM, 1KB of SRAM, and 54 programmable I/O lines. It features a powerful AVR 8-bit RISC processor, various timers, an ADC, serial interfaces, and low-power sleep modes. The microcontroller is supported by development tools and can be programmed in-system through its SPI interface.
The P89LPC920/921/922/9221 are 8-bit microcontrollers with a two-clock 80C51 core and features including 2-8kB of flash memory, 256B of RAM, two timers, analog comparators, UART, I2C, and oscillator options. They are designed for applications requiring low cost and power solutions and integrate many system functions to reduce component count. Key features include flash programming, power saving modes, watchdog timer, and EMI reduction.
The document introduces the SmartLEWISTM MCU from Infineon, a single chip with an integrated 8051 microcontroller and ASK/FSK multi-band transmitter for sub-1GHz ISM frequency bands. It has flexibility in design, high level integration, and various power and sensor interfaces. Main applications include remote controls, home automation, security systems, and wireless sensor networks.
The MC9RS08KA8/4 microcontroller unit is a low-cost MCU with an RS08 core, 8K flash, 254B RAM, 12-channel 10-bit ADC, and 18 I/O pins. It is intended for applications like home appliances, medical equipment, and general purpose use. The document provides an overview of the features and applications of the MC9RS08KA8/4 MCU and recommends additional resources for ordering samples and getting technical support.
X-prog M ECU programmer V5.50 users manualbuyobdii
The XPROG-m supports in-circuit and on-board programming of Motorola 68HC05, 68HC08, 68HC11, 68HC(S)12 family MCU's, Texas Instruments TMS370/TMS374 family MCU's and serial EEPROM's .
All supported devices are divided into "Software authorization" licenses. You can obtain authorization license only for these devices you are interested in.
http://www.eobd2.fr/new-xprog-m-v50-xprog-m-programmer-v50-204.html
Flextronics is implementing an HRIS system globally using Workday in phases, with the goal of a full rollout across 23 countries and over 100,000 employees within one year. The first phase included the US, Canada and Mexico, with the second phase piloting in China and India. Selecting the right project team and ensuring executive sponsorship were keys to success. Global design required reviewing business processes across countries and gaining consensus through debate. Change management was challenging due to the need to change mindsets across different HR functions, managers and employees. The next phases will focus on additional country implementations, global HR processes, and leveraging more Workday functionality.
WorkDay-surviving and thriving in a world of changeSatya Harish
This document summarizes TripAdvisor's experience transitioning their finance functions to Workday's cloud-based platform. It discusses how Workday provides TripAdvisor with increased visibility, flexibility, and productivity. It also details how Workday allows TripAdvisor to operate with a complete picture through unified HR and finance on an always up-to-date system. The transition has reduced TripAdvisor's costs and complexity while improving controls.
This document provides an overview of Scrum, an agile framework for managing product development. It describes Scrum's event-driven process, including sprints, daily stand-ups, sprint reviews and retrospectives. Key Scrum roles like Product Owner, Scrum Master and team are defined. The document also covers Scrum artifacts like the product and sprint backlogs and how user stories are used to capture product requirements in Scrum.
O - Oracle application testing suite test starter kits for oracle e business ...Satya Harish
The document provides details on test scripts included in the Oracle Application Testing Suite Test Starter Kit for automated functional and load testing of Oracle E-Business Suite R12 and 11i. It includes 18 automated functional test scripts covering various EBS transactions and 19 automated load test scripts, including individual transaction scripts and end-to-end transaction flows. Instructions are provided on how to execute the test scripts in Oracle Functional Testing and Oracle Load Testing.
This document provides an introduction to Visual Basic 2008, including:
1. A brief description of Visual Basic 2008 and its evolution from earlier versions of BASIC. It is now a fully object-oriented programming language.
2. An overview of the Visual Basic 2008 Integrated Development Environment and how to create a new project.
3. Instructions for creating a simple first program to demonstrate adding two numbers and displaying the result in a message box.
G03.2014 Intelligent Business Process Management SuitesSatya Harish
The document discusses the benefits of exercise for mental health. Regular physical activity can help reduce anxiety and depression and improve mood and cognitive functioning. Exercise causes chemical changes in the brain that may help protect against mental illness and improve symptoms.
G05.2013 Critical Capabilities for SIEMSatya Harish
The document discusses the benefits of exercise for mental health. Regular physical activity can help reduce anxiety and depression and improve mood and cognitive function. Exercise causes chemical changes in the brain that may help alleviate symptoms of mental illness and boost overall mental well-being.
The document discusses the benefits of exercise for mental health. Regular physical activity can help reduce anxiety and depression and improve mood and cognitive functioning. Exercise causes chemical changes in the brain that may help protect against mental illness and improve symptoms.
This document provides an overview and analysis of the secure web gateway (SWG) market. It discusses key findings from Gartner's research, including:
- The market remains dominated by traditional on-premises appliances, but cloud-based services are growing rapidly. Advanced threat protection is an important differentiation factor.
- Vendors vary significantly in their cloud service offerings and abilities to protect against advanced threats. Integration of network sandboxing with SWGs is an important area of competition.
- Organizations considering cloud services have many options, but vendors differ in cloud strategy and sales/distribution effectiveness. Advanced threat services are now required for effective cloud-based SWGs.
G11.2013 Application Development Life Cycle ManagementSatya Harish
This document provides an overview and analysis of the application development life cycle management (ADLM) tool market. It evaluates leading ADLM vendors to help organizations select appropriate technology partners. The document includes descriptions of key ADLM capabilities, an analysis of changes in the market, and assessments of the strengths and weaknesses of vendors such as Atlassian, Borland, CollabNet, and Hansoft.
G06.2014 Security Information and Event ManagementSatya Harish
The document summarizes a Gartner report on the security information and event management (SIEM) market. It defines the SIEM market as addressing the need to analyze security event data in real time for threat management and collect/analyze log data for incident response and compliance. The report evaluates SIEM vendors and places them in a magic quadrant based on their completeness of vision and ability to execute. It provides strengths and cautions for various vendors, including AccelOps and AlienVault.
G05.2013 Security Information and Event ManagementSatya Harish
This document provides a summary and analysis of the security information and event management (SIEM) market. It defines the SIEM market as addressing the need to analyze security event data in real time for threat management and to collect and analyze log data for incident response and compliance. The document discusses several major vendors in the SIEM space, including their product offerings, target markets, strengths, and cautions. It analyzes vendors like AlienVault, EiQ Networks, EMC-RSA, and EventTracker and their SIEM technologies.
G05.2015 - Magic quadrant for cloud infrastructure as a serviceSatya Harish
This document provides a summary of Gartner's 2015 Magic Quadrant report on cloud infrastructure as a service (IaaS) providers worldwide. It defines cloud IaaS and outlines the evaluation criteria used to assess providers, including their ability to execute on products/services and customer experience, as well as vision. The report evaluates major public and private cloud IaaS providers and provides an assessment of their strengths and cautions for customers to be aware of.
G05.2014 - Magic quadrant for cloud infrastructure as a serviceSatya Harish
This document provides an overview and evaluation criteria for Gartner's 2014 Magic Quadrant for cloud infrastructure as a service (IaaS). It defines cloud IaaS and distinguishes it from other cloud services. The document evaluates IaaS providers based on their ability to execute and completeness of vision. Key criteria include availability, scalability, security, pricing and support. While the IaaS market continues rapid growth, strategic provider selection is important given the immaturity of some offerings.
BOOK - IBM tivoli netcool service quality manager data mediation gateway deve...Satya Harish
This document provides information about developing data mediation gateways for IBM Tivoli Netcool Service Quality Manager. It discusses Service Quality Manager concepts and architecture. It then describes how to develop a gateway, including identifying the data source, configuring the gateway, developing the transfer and parsing processes, and testing the gateway. Sample code is provided in an appendix. The goal of the gateway is to transfer data from an external source into a format that Service Quality Manager can process to monitor service quality.
The document is a book about managing packages in DB2 9 for z/OS. It discusses packages, which are collections of SQL statements that are bound together. The book covers topics like how packages are identified and executed, the BIND options used to manage packages, and maintaining access plan stability. It is intended to help readers learn about packages, understand how they are used, and properly manage local and remote packages.
BOOK - IBM Z vse using db2 on linux for system zSatya Harish
The document is a technical guide about using DB2 on Linux for System z. It provides information on planning, setting up, and customizing a DB2 environment where some data is hosted on z/VSE and accessed using DB2 on Linux for System z. The guide covers topics like hardware planning, database considerations, installing and configuring DB2 and related software, and setting up networking and connectivity between the z/VSE and Linux systems.
This document provides information about security features in IBM z/VSE, including the Basic Security Manager (BSM). It discusses how BSM uses System Authorization Facility to control access to resources through security files. It also covers LDAP sign-on support, which allows users to sign on with their LDAP credentials instead of a z/VSE user ID. The document provides guidance on installing, customizing, administering and backing up BSM, as well as configuring and activating LDAP sign-on support on z/VSE.
Building a Raspberry Pi Robot with Dot NET 8, Blazor and SignalRPeter Gallagher
In this session delivered at NDC Oslo 2024, I talk about how you can control a 3D printed Robot Arm with a Raspberry Pi, .NET 8, Blazor and SignalR.
I also show how you can use a Unity app on an Meta Quest 3 to control the arm VR too.
You can find the GitHub repo and workshop instructions here;
https://bit.ly/dotnetrobotgithub
1. The LPC microcontroller portfolio builds on 10 years of leadership and includes more than 400 32-bit devices, covering every application class, from entry-level designs to
high-end systems that run Linux OS. This selection guide is a starting point for choosing a specific device. For the latest product information, and to find MCUs by series, core, key
feature or application, visit www.nxp.com/microcontrollers.
NXP LPC Microcontrollers
Q1 2015
ARM®
CortexTM
-M Cores
Representing the very latest innovations in 32-bit technology, performance, power efficiency, and scalability, the LPC portfolio includes best-in-class options for every Cortex-M
architecture (Cortex-M0+, Cortex-M0, Cortex-M3, Cortex-M4, and multi-core).
LPC800 Series I Low power, basic control and connectivity I Cortex-M0+
Available in low-pin-count packages, such as TSSOP, these 30 MHz MCUs offer exceptional power efficiency, 32-bit control, and basic connectivity, ideal for addressing 8- and 16-bit application
requirements.
Part no.
Memory Timers Serial interfaces Analog
GPIO
Maxclockspeed
(MHz)
Supplyvoltage(V)
Temperaturerange
(°C)
Package Notes
Flash(kB)
Flashpage(B)
RAM(kB)
Standardtimers1
PWMchannels2
State-configurable
timer(SCTimer/
PWM)3
UART
I2C
SPI
ADCchannels
/resolution
Samplerate
Comparator
LPC811 8 64 2 5 4 1 2 1 1 1 14 30 1.8-3.6 -40 to +105 TSSOP16 Switch matrix, reduced-power modes, brownout detection, power-on reset
LPC812 16 64 4 5 4 1 3 1 2 1 18 30 1.8-3.6 -40 to +105 SO20, TSSOP16/20, XSON16 Switch matrix, reduced-power modes, brownout detection, power-on reset
LPC822 16 64 4 6 8 1 3 4 2 12 ch/12 b 1.2 Msps 1 29 30 1.8-3.6 -40 to +105 TSSOP20, HVQFN33 Switch matrix, pattern-match engine, reduced-power modes, brownout detection, power-on reset
LPC824 32 64 8 6 8 1 3 4 2 12 ch/12 b 1.2 Msps 1 29 30 1.8-3.6 -40 to +105 TSSOP20, HVQFN33 Switch matrix, pattern-match engine, reduced-power modes, brownout detection, power-on reset
1
Includes multi-rate timer (MRT), self wake-up timer, systick timer, and SCTimer/PWM configured as two 16-bit timers
2
Includes use of SCTimer/PWM as PWM
3
SCTimer/PWM peripheral can be configured to provide additional timers and/or PWM channels
What sets LPC devices apart?
Power, performance, and features to address 8-, 16-, and 32-bit MCU
applications
The expertise and technology to solve unique application problems
Access to one of the broadest semiconductor portfolios in the industry
Complete application solutions from one company
Robust software ecosystem and developer support community
2. 2
LPC1100 Series I Low power, broad selection, industry-standard connectivity I Cortex-M0+ & M0
These Cortex-M0+ and Cortex-M0 MCUs deliver exceptional power efficiency for longer battery life, and performance headroom for product enhancements. They provide an upgrade path for the
Cortex-M0+ LPC800 Series.
Part no.
Memory Timers Serial interfaces Analog
RTC
GPIO
Maxclockspeed
(MHz)
Supplyvoltage(V)
Temperaturerange
(°C)
Package Notes
Flash(kB)
Flashpage(B)
RAM(kB)
EEPROM(kB)
Standardtimers1
PWMchannels2
State-configurable
timer(SCTimer/
PWM)3
UART
I2C
SPI
I2S
USBdevice4
CAN
ADCchannels/
resolution
Samplerate
DAC
Comparator
LPC11xx: Low-pin count, low-power Cortex-M0
LPC1102 32 256 8 6 7 1 1 1 5 ch/10 b 400 ksps 11 50 1.8-3.6 -40 to +85 WLCSP16 ROM power profiles, 5V-tolerant I/O
LPC1104 32 256 8 6 8 1 1 1 5 ch/10 b 400 ksps 13 50 1.8-3.6 -40 to +85 WLCSP16 ROM power profiles, 5V-tolerant I/O
LPC1110 4 256 1 6 8 1 1 1 5 ch/10 b 400 ksps 16 50 1.8-3.6 -40 to +85 SO20 On-chip PMU, ROM power profiles
LPC1111 8 256 2/4 6 8/11 1 1 1 5/6/8 ch/10 b 400 ksps Up to 28 50 1.8-3.6 -40 to +85 TSSOP20, HVQFN33
On-chip PMU, ROM power profiles,
5V-tolerant I/O
LPC1112 16 256 2/4 6 8/11 1 1 1 5/6/8 ch/10 b 400 ksps Up to 28 50 1.8-3.6 -40 to +85
SO20, TSSOP20/28,
HVQFN24/33
On-chip PMU, ROM power profiles,
5V-tolerant I/O
LPC1113 24 256 4/8 6 11 1 1 1-2 8 ch/10 b 400 ksps 28/42 50 1.8-3.6 -40 to +85 HVQFN33, LQFP48 ROM power profiles, 5V-tolerant I/O
LPC1114 32 256 4/8 6 10/11 1 1 1-2 6/8 ch/10 b 400 ksps Up to 42 50 1.8-3.6 -40 to +85
TSSOP28,
HVQFN33, LQFP48
On-chip PMU, ROM power profiles,
5V-tolerant I/O
LPC1115 64 256 8 6 11 1 1 2 8 ch/10 b 400 ksps 42 50 1.8-3.6 -40 to +105 LQFP48, TFBGA48 ROM power profiles, 5V-tolerant I/O
LPC1124 32 256 8 6 11 3 1 2 8 ch/12 b 2 Msps 38 50 1.8-3.6 -40 to +105 LQFP48 ROM EEPROM drivers & power profiles
LPC1125 64 256 8 6 11 3 1 2 8 ch/12 b 2 Msps 38 50 1.8-3.6 -40 to +105 LQFP48 ROM EEPROM drivers & power profiles
LPC11xxLV: 1.8 V Cortex-M0
LPC1101LV 32 256 2 6 10 1 1 1 6 ch/8 b 400 ksps 21 50 1.65-1.95 -40 to +85 WLCSP25 Tiny package, unique ID
LPC1102LV 32 256 8 6 10 1 1 1 6 ch/8 b 400 ksps 21 50 1.65-1.95 -40 to +85 WLCSP25 Tiny package, unique ID
LPC1112LV 16 256 2/4 6 9/11 1 1 1
6 ch/8 b or
6 ch/10 b
400 ksps 20/27 50 1.65-1.95 -40 to +85 HVQFN24/33 Unique ID
LPC1114LV 32 256 4/8 6 11 1 1 1
6 ch/8 b or
6 ch/10 b
400 ksps 20/27 50 1.65-1.95 -40 to +85 HVQFN24/33 Unique ID
LPC11Axx: Analog Cortex-M0
LPC11A02 16 256 4 2 6 10 1 1 1 8 ch/10 b 400 ksps 10 b 1 18 50 1.8-3.6 -40 to +85 WLCSP20 VREF, UVLO protection
LPC11A04 32 256 8 4 6 10 1 1 1 8 ch/10 b 400 ksps 10 b 1 18 50 1.8-3.6 -40 to +85 WLCSP20 VREF, UVLO protection
LPC11A11 8 256 2 512 b 6 12 1 1 2 8 ch/10 b 400 ksps 10 b 1 28 50 1.8-3.6 -40 to +85 HVQFN33 VREF, UVLO protection
LPC11A12 16 256 4 1 6 12 1 1 2 8 ch/10 b 400 ksps 10 b 1 28/42 50 1.8-3.6 -40 to +85 HVQFN33, LQFP48 VREF, UVLO protection
LPC11A13 24 256 6 2 6 12 1 1 2 8 ch/10 b 400 ksps 10 b 1 28 50 1.8-3.6 -40 to +85 HVQFN33 VREF, UVLO protection
LPC11A14 32 256 8 4 6 12 1 1 2 8 ch/10 b 400 ksps 10 b 1 28/42 50 1.8-3.6 -40 to +85 HVQFN33, LQFP48 VREF, UVLO protection
LPC11Cxx: CAN Cortex-M0
LPC11C12 16 256 8 6 11 1 1 2 1 8 ch/10 b 400 ksps 42 50 1.8-3.6 -40 to +85 LQFP48
C_CAN, USART, SmartCard, ROM EEPROM
drivers & power profiles
LPC11C14 32 256 8 6 11 1 1 2 1 8 ch/10 b 400 ksps 42 50 1.8-3.6 -40 to +85 LQFP48
C_CAN, USART, SmartCard, ROM EEPROM
drivers & power profiles
LPC11C22 16 256 8 6 10 1 1 2 1 8 ch/10 b 400 ksps 36 50 1.8-3.6 -40 to +85 LQFP48
C_CAN & CAN txcvr, USART, SmartCard,
ROM EEPROM drivers & power profiles
LPC11C24 32 256 8 6 10 1 1 2 1 8 ch/10 b 400 ksps 36 50 1.8-3.6 -40 to +85 LQFP48
C_CAN & CAN txcvr, USART, SmartCard,
ROM EEPROM drivers & power profiles
LPC11Dxx: Cortex-M0 with LCD driver
LPC11D14 32 256 8 6 11 1 1 2 8 ch/10 b 400 ksps 42 50 1.8-3.6 -40 to +85 LQFP100
LPC1114 with integrated 40x4 segment
LCD driver
LPC11Exx: EEPROM Cortex-M0
LPC11E11 8 256 4 512 b 6 11 1 1 2 8 ch/10 b 400 ksps 28 50 1.8-3.6 -40 to +85 HVQFN33
ROM EEPROM drivers & power profiles,
32-bit divide libraries
www.nxp.com/microcontrollers
3. 3
Part no.
Memory Timers Serial interfaces Analog
RTC
GPIO
Maxclockspeed
(MHz)
Supplyvoltage(V)
Temperaturerange
(°C)
Package Notes
Flash(kB)
Flashpage(B)
RAM(kB)
EEPROM(kB)
Standardtimers1
PWMchannels2
State-configurable
timer(SCTimer/
PWM)3
UART
I2C
SPI
I2S
USBdevice4
CAN
ADCchannels/
resolution
Samplerate
DAC
Comparator
LPC11E12 16 256 6 1 6 11 1 1 2 8 ch/10 b 400 ksps 40 50 1.8-3.6 -40 to +85 LQFP48
ROM EEPROM drivers & power profiles,
32-bit divide libraries
LPC11E13 24 256 8 2 6 11 1 1 2 8 ch/10 b 400 ksps 40 50 1.8-3.6 -40 to +85 LQFP48
ROM EEPROM drivers & power profiles,
32-bit divide libraries
LPC11E14 32 256 10 4 6 11 1 1 2 8 ch/10 b 400 ksps 28/40/54 50 1.8-3.6 -40 to +85
LQFP48/64,
HVQFN33
ROM EEPROM drivers & power profiles,
32-bit divide libraries
LPC11E36 96 256 12 4 6 11 1 1 2 8 ch/10 b 400 ksps 28/54 50 1.8-3.6 -40 to +85 LQFP64, HVQFN33
ROM EEPROM drivers & power profiles,
32-bit divide libraries
LPC11E37 128 256 12 4 6 11 1 1 2 8 ch/10 b 400 ksps 40/54 50 1.8-3.6 -40 to +85 LQFP48/64
ROM EEPROM drivers & power profiles,
32-bit divide libraries
LPC11E37H 128 256 12 4 6 11 25 2 2 16 8 ch/10 b 400 ksps 40/54 50 1.8-3.6 -40 to +85 LQFP64
LPC11E37 with I/O Handler for enhanced
I2
S/UART functionality & DMA transfers
LPC11E6x: EEPROM Cortex-M0+ with 12-bit ADC
LPC11E66 64 256 12 4 6 14 2 4 2 2 8 ch/12 b 2 Msps 1 36 50 1.8-3.6 -40 to +105 LQFP48 ROM EEPROM drivers & power profiles
LPC11E67 128 256 20 4 6 19 2 5 2 2 12 ch/12 b 2 Msps 1 36/50/80 50 1.8-3.6 -40 to +105
LQFP48, LQFP64,
LQFP100
ROM EEPROM drivers & power profiles
LPC11E68 256 256 36 4 6 19 2 5 2 2 12 ch/12 b 2 Msps 1 36/50/80 50 1.8-3.6 -40 to +105
LQFP48, LQFP64,
LQFP100
ROM EEPROM drivers & power profiles
LPC11Uxx: USB Cortex-M0
LPC11U12 16 256 6 6 11 1 1 2 1x FS 8 ch/10 b 400 ksps 26/40 50 1.8-3.6 -40 to +85 LQFP48, HVQFN33
ROM USB drivers & power profiles, 32-bit
divide libraries, 5V-tolerant I/O
LPC11U13 24 256 6 6 11 1 1 2 1x FS 8 ch/10 b 400 ksps 40 50 1.8-3.6 -40 to +85 LQFP48
ROM USB drivers & power profiles, 32-bit
divide libraries, 5V-tolerant I/O
LPC11U14 32 256 6 6 11 1 1 2 1x FS 8 ch/10 b 400 ksps 26/40 50 1.8-3.6 -40 to +85
HVQFN33, LQFP48,
TFBGA48
ROM USB drivers & power profiles, 32-bit
divide libraries, 5V-tolerant I/O
LPC11U23 24 256 8 1 6 11 1 1 2 1x FS 8 ch/10 b 400 ksps 40 50 1.8-3.6 -40 to +85 LQFP48
ROM USB drivers & power profiles, 32-bit
divide libraries, 5V-tolerant I/O
LPC11U24 32 256 6/8 2/4 6 11 1 1 2 1x FS 8 ch/10 b 400 ksps 26/40/54 50 1.8-3.6 -40 to +85
HVQFN33, TFBGA48,
LQFP48/64
ROM USB drivers & power profiles, 32-bit
divide libraries, 5V-tolerant I/O
LPC11U34 40/48 256 8/10 4 6 11 1 1 2 1x FS 8 ch/10 b 400 ksps 26/40 50 1.8-3.6 -40 to +85 LQFP48, HVQFN33
ROM USB drivers & power profiles, 32-bit
divide libraries, 5V-tolerant I/O
LPC11U35 64 256 10/12 4 6 11 1 1 2 1x FS 8 ch/10 b 400 ksps 40/54 50 1.8-3.6 -40 to +85
LQFP48/64,
HVQFN33, TFBGA48
ROM USB drivers & power profiles, 32-bit
divide libraries, 5V-tolerant I/O
LPC11U36 96 256 10/12 4 6 11 1 1 2 1x FS 8 ch/10 b 400 ksps 40/54 50 1.8-3.6 -40 to +85 LQFP48/64
ROM USB drivers & power profiles, 32-bit
divide libraries, 5V-tolerant I/O
LPC11U37 128 256 10/12 4 6 11 1 1 2 1x FS 8 ch/10 b 400 ksps 40/54 50 1.8-3.6 -40 to +85 LQFP48/64
ROM USB drivers & power profiles, 32-bit
divide libraries, 5V-tolerant I/O
LPC11U37H 128 256 10/12 4 6 11 25 2 2 16 1x FS 8 ch/10 b 400 ksps 26/40 50 1.8-3.6 -40 to +85 LQFP64
LPC11U37 with I/O Handler for enhanced
SPI/UART functionality & DMA transfers
LPC11U6x: Cortex-M0+
LPC11U66 64 256 12 4 11 14 2 3 2 2 1x FS 8 ch/12 b 2 Msps 1 34 50 2.4-3.6 -40 to +105 LQFP48
ROM USB drivers & power profiles, 32-bit
divide, temp sensor
LPC11U67 128 256 16 4 117
148 2 3 2 2 1x FS 8 ch/12 b 2 Msps 1 34 50 2.4-3.6 -40 to +105 LQFP48
ROM USB drivers & power profiles, 32-bit
divide, temp sensor
LPC11U68 256 256 32 4 117
17/198 2 5 2 2 1x FS
10 ch/12 b or
12 ch/12 b
2 Msps 1 34/48/80 50 2.4-3.6 -40 to +105 LQFP48/64/100
ROM USB drivers & power profiles, 32-bit
divide, temp sensor
LPC1100 Series (continued)
1
Includes Watchdog timer and systick timer
2
Using timers 0-3
3
SCTimer/PWM peripheral can be configured as additional timers and/or PWM channels
4
FS = Full Speed
5
Includes I/O Handler used as UART
6
Includes I/O Handler used as I2
S interface
7
Includes timers 0-3, SCTimer/PWMs configured as four 16-bit timers, one Watchdog timer, one real-time clock,
and one systick timer
8
Includes timers 0-3 and SCTimer/PWMs as PWM (LPC11U68 configuration is package-dependent)
www.nxp.com/microcontrollers
4. 4
LPC1200 Series I Noise immunity for industrial applications I Cortex-M0
Delivering extra reliability in electrically challenging environments, these Cortex-M0 MCUs are optimized for industrial control and home appliances, and are available with an LCD driver.
LPC1300 Series I Performance & basic connectivity, LPC1100 upgrade I Cortex-M3
Operating at clock speeds up to 72 MHz and available with a Full Speed USB controller, these Cortex-M3 MCUs provide a performance upgrade path for LPC1100 and LPC11U00 devices.
Part no.
Memory Timers Serial interfaces Analog
RTC
GPIO
Maxclockspeed
(MHz)
Supplyvoltage(V)
Temperaturerange
(°C)
Package Notes
Flash(kB)
Flashsector(B)
RAM(kB)
Standardtimers1
PWMchannels2
UART
I2C
SPI
ADCchannels/
resolution
Samplerate
Comparator
LPC1224 32/48 256 4 7 10 2 1 1 8 ch/10 b 400 ksps 2 1 39/55 30 3.2-3.6 -40 to +85 LQFP48/64 Additional DMA, CRC, RS-485
LPC1225 64/80 256 8 7 10 2 1 1 8 ch/10 b 400 ksps 2 1 39/55 30 3.2-3.6 -40 to +85 LQFP48/64 Additional DMA, CRC, RS-485
LPC1226 96 256 8 7 10 2 1 1 8 ch/10 b 400 ksps 2 1 39/55 30 3.2-3.6 -40 to +85 LQFP48/64 Additional DMA, CRC, RS-485
LPC1227 128 256 8 7 10 2 1 1 8 ch/10 b 400 ksps 2 1 39/55 30 3.2-3.6 -40 to +85 LQFP48/64 Additional DMA, CRC, RS-485
LPC12D27 128 256 8 7 10 2 1 1 8 ch/10 b 400 ksps 2 1 39 50 3.2-3.6 -40 to +85 LQFP100 LPC1227 with integrated 40x4 segment LCD driver
Part no.
Memory Timers Serial interfaces Analog
Package Notes
Flash(kB)
RAM(kB)
EEPROM(kB)
Standardtimers1
PWMchannels2
UART
I2C
SPI
USBdevice3
ADCchannels/
resolution
Samplerate
GPIO
Maxclockspeed
(MHz)
Supplyvoltage(V)
Temperaturerange
(°C)
LPC131x
LPC1311 8 4 6 11 1 1 1 8 ch/10 b 400 ksps 28 72 2.0-3.6 -40 to +85 HVQFN33 ROM EEPROM drivers & power profiles, USART, SmartCard
LPC1313 32 8 6 11 1 1 1 8 ch/10 b 400 ksps 28/42 72 2.0-3.6 -40 to +85 LQFP48, HVQFN33 ROM EEPROM drivers & power profiles, USART, SmartCard
LPC1315 32 8 2 7 11 1 1 2 8 ch/12 b 500 ksps 28/51 72 2.0-3.6 -40 to +85 LQFP48/64, HVQFN33 ROM EEPROM drivers & power profiles, USART, SmartCard
LPC1316 48 8 4 7 11 1 1 2 8 ch/12 b 500 ksps 28/51 72 2.0-3.6 -40 to +85 LQFP48/64, HVQFN33 ROM EEPROM drivers & power profiles, USART, SmartCard
LPC1317 64 10 4 7 11 1 1 2 8 ch/12 b 500 ksps 28/51 72 2.0-3.6 -40 to +85 LQFP48/64, HVQFN33 ROM EEPROM drivers & power profiles, USART, SmartCard
LPC134x: USB
LPC1342 16 4 6 11 1 1 1 1x FS 8 ch/10 b 400 ksps 28 72 2.0-3.6 -40 to +85 LQFP48, HVQFN33 USB device-only controller, ROM USB & EEPROM drivers & power profiles
LPC1343 32 8 6 11 1 1 1 1x FS 8 ch/10 b 400 ksps 28/42 72 2.0-3.6 -40 to +85 LQFP48, HVQFN33 USB device-only controller, ROM USB & EEPROM drivers & power profiles
LPC1345 32 10 2 7 11 1 1 2 1x FS 8 ch/12 b 500 ksps 28/51 72 2.0-3.6 -40 to +85 LQFP48/64, HVQFN33
USB device-only controller, ROM USB & EEPROM drivers & power profiles in ROM, USART,
SmartCard
LPC1346 48 10 4 7 11 1 1 2 1x FS 8 ch/12 b 500 ksps 28/51 72 2.0-3.6 -40 to +85 LQFP48/64, HVQFN33
USB device-only controller, ROM USB & EEPROM drivers & power profiles in ROM, USART,
SmartCard
LPC1347 64 12 4 7 11 1 1 2 1x FS 8 ch/12 b 500 ksps 28/51 72 2.0-3.6 -40 to +85 LQFP48/64, HVQFN33
USB device-only controller, ROM USB & EEPROM drivers & power profiles in ROM, USART,
SmartCard
1
Includes Watchdog timer, systick timer, and real-time clock
2
Using timers 0-3
1
Includes Watchdog timer and systick timer; LPC13x5, LPC13x6,
and LPC13x7 add repetitive-interrupt timer
2
Using timers 0-3
3
FS = Full Speed
www.nxp.com/microcontrollers
5. 5
LPC1500 Series I High-precision motion control I Cortex-M3
Optimized for motor control, these low-power Cortex-M3 MCUs provide a long list of peripherals, including Full Speed USB, a CAN controller, an advanced PWM/timer subsystem, and two high-speed 12-bit ADCs.
Memory Timers Serial interfaces Analog
RTC
GPIO
Maxclockspeed
(MHz)
Supplyvoltage(V)
Temperaturerange
(°C)
Package NotesPart no.
Flash(kB)
RAM(kB)
EEPROM(kB)
Standardtimers1
PWMchannels2
State-configurable
timer(SCTimer/
PWM)3
UART
I2C
SPI
USBdevice
CAN
ADCchannels/
resolution
Samplerate
DAC
Comparator
LPC1517 64 12 4 13 28 4 3 1 2 1 2x 12 ch/12 b 2 Msps 12 b 4 1 32/46 72 2.4-3.6 -40 to +105 LQFP48/64 Switch matrix, QEI
LPC1518 128 20 4 13 28 4 3 1 2 1 2x 12 ch/12 b 2 Msps 12 b 4 1 46/78 72 2.4-3.6 -40 to +105 LQFP64/100 Switch matrix, QEI
LPC1519 256 36 4 13 28 4 3 1 2 1 2x 12 ch/12 b 2 Msps 12 b 4 1 46/78 72 2.4-3.6 -40 to +105 LQFP64/100 Switch matrix, QEI
LPC1547 64 12 4 13 28 4 3 1 2 1x FS 1 2x 12 ch/12 b 2 Msps 12 b 4 1 30/44 72 2.4-3.6 -40 to +105 LQFP48/64 USB device-only controller, switch matrix, QEI
LPC1548 128 20 4 13 28 4 3 1 2 1x FS 1 2x 12 ch/12 b 2 Msps 12 b 4 1 44/76 72 2.4-3.6 -40 to +105 LQFP64/100 USB device-only controller, switch matrix, QEI
LPC1549 256 36 4 13 28 4 3 1 2 1x FS 1 2x 8/12 ch/12 b 2 Msps 12 b 4 1 30/76 72 2.4-3.6 -40 to +105 LQFP48/64/100 USB device-only controller, switch matrix, QEI
1
Includes multi-rate timer, repetitive-interrupt timer, Windowed Watchdog timer, systick
timer, real-time clock, and each SCTimer/PWM configured as two 16-bit timers
2
Includes use of SCTimer/PWMs as PWM (maximum number depends on package)
3
SCTimer/PWM peripheral can be configured as additional timers and/or PWM channels
www.nxp.com/microcontrollers
LPC54100 Series I Ultra-low power for always-on sensor processing I Cortex-M4F/M0+
Designed for always-on sensor processing applications, these ultra-low-power, single- and dual-core Cortex-M4F/M0+ MCUs deliver best-in-class power efficiency and scalable power/performance
Part no.
Core Memory Timers
Serial
interfaces
Analog
Cortex-M0+
Cortex-M4Fwith
FloatingPointUnit
Flash(kB)
RAM(kB)
Standardtimers1
PWMchannels2
State-configurable
timer(SCTimer/
PWM)3
UART
I2
C
SPI
ADCchannels
/resolution
Samplerate
RTC
GPIO
Maxclockspeed
(MHz)
Supplyvoltage(V)
Temperaturerange
(°C)
Package Notes
LPC54101 1 256/512 104 5 6 1 4 3 2 12 ch/12 b 4.8 Msps 1 50 100 1.62-3.6 -40 to +105 WLCSP49, LQFP64 Single Cortex-M4F core, low-power ADC, small form factor
LPC54102 1 1 256/512 104 5 6 1 4 3 2 12 ch/12 b 4.8 Msps 1 50 100 1.62-3.6 -40 to +105 WLCSP49, LQFP64
Dual Cortex-M4F/M0+ core, one ultra-low power core for sensor
listening, aggregation, fusion and communication, small form factor
1
Includes Watchdog timer, real-time alarm clock, repetitive-interrupt timer, systick timer, and SCTimer/PWM configured as two 16-bit timers
2
SCTimer/PWM peripheral can be configured as additional timers and/or PWM channels
LPC1700 Series I High performance, multi-connectivity, advanced peripherals I Cortex-M3
With a range of advanced connectivity and display options, these Cortex-M3 MCUs provide an upgrade path for the ARM7 LPC2300.
Part no.
Memory Timers Serial interfaces Analog
RTC
LCDcontroller
SD/MMC
Externalbus
interface(bits)
GPIO
Maxclockspeed
(MHz)
Supplyvoltage(V)
Temperature
range(°C)
Package Notes
Flash(kB)
RAM(kB)
EEPROM(kB)
Standard
timers1
PWM
channels2
UART
I2C
SPI
I2S
USBdevice/
host/OTG3
CAN
Ethernet
ADCchannels/
resolution
Samplerate
DAC
LPC1751 32 8 10 12 4 3 2 1x FS 1 6 ch/12 b 400 ksps 1 52 100 2.4-3.6 -40 to +85 LQFP80 QEI, motor-control PWM
LPC1752 64 16 10 12 4 3 2 1x FS 1 6 ch/12 b 400 ksps 1 52 100 2.4-3.6 -40 to +85 LQFP80 QEI, motor-control PWM
LPC1754 128 32 10 12 4 3 2 1x FS 1 6 ch/12 b 400 ksps 10 b 1 52 100 2.4-3.6 -40 to +85 LQFP80 QEI, motor-control PWM
LPC1756 256 32 10 12 4 3 2 1 1x FS 2 6 ch/12 b 400 ksps 10 b 1 52 100 2.4-3.6 -40 to +85 LQFP80 QEI, motor-control PWM
LPC1758 512 64 10 12 4 3 2 1 1x FS 2 1 6 ch/12 b 400 ksps 10 b 1 52 100 2.4-3.6 -40 to +85 LQFP80 QEI, motor-control PWM
LPC1759 512 64 10 12 4 3 2 1 1x FS 2 6 ch/12 b 400 ksps 10 b 1 52 100 2.4-3.6 -40 to +85 LQFP80 QEI, motor-control PWM
6. 6
1
Includes Watchdog timer, systick timer, motor-control timer, PWM timer, and real-time clock; LPC177x/8x adds a repetitive-interrupt timer
2
Using motor-control PWM and one (LPC175x/6x) or two (LPC177x/8x) general-purpose PWMs
3
FS = Full Speed
www.nxp.com/microcontrollers
Part no.
Memory Timers Serial interfaces Analog
RTC
LCDcontroller
SD/MMC
Externalbus
interface(bits)
GPIO
Maxclockspeed
(MHz)
Supplyvoltage(V)
Temperature
range(°C)
Package NotesFlash(kB)
RAM(kB)
EEPROM(kB)
Standard
timers1
PWM
channels2
UART
I2C
SPI
I2S
USBdevice/
host/OTG3
CAN
Ethernet
ADCchannels/
resolution
Samplerate
DAC
LPC1763 256 64 10 12 4 3 2 1 8 ch/12 b 400 ksps 10 b 1 70 100 2.4-3.6 -40 to +85 LQFP100 QEI, motor-control PWM
LPC1764 128 32 10 12 4 3 2 1x FS 2 1 8 ch/12 b 400 ksps 1 70 100 2.4-3.6 -40 to +85 LQFP100 QEI, motor-control PWM
LPC1765 256 64 10 12 4 3 2 1 1x FS 2 8 ch/12 b 400 ksps 10 b 1 70 100 2.4-3.6 -40 to +85 LQFP100, TFBGA100 QEI, motor-control PWM
LPC1766 256 64 10 12 4 3 2 1 1x FS 2 1 8 ch/12 b 400 ksps 10 b 1 70 100 2.4-3.6 -40 to +85 LQFP100 QEI, motor-control PWM
LPC1767 512 64 10 12 4 3 2 1 1 8 ch/12 b 400 ksps 10 b 1 70 100 2.4-3.6 -40 to +85 LQFP100 QEI, motor-control PWM
LPC1768 512 64 10 12 4 3 2 1 1x FS 2 1 8 ch/12 b 400 ksps 10 b 1 70 100 2.4-3.6 -40 to +85 LQFP100, TFBGA100 QEI, motor-control PWM
LPC1769 512 64 10 12 4 3 2 1 1x FS 2 1 8 ch/12 b 400 ksps 10 b 1 70 120 2.4-3.6 -40 to +85 LQFP100 QEI, motor-control PWM
LPC1774 128 40 2 9 18 4 3 3 1 1x FS 2 8 ch/12 b 400 ksps 10 b 1 8/32 109/165 120 2.4-3.6 -40 to +85 LQFP144/208 QEI, motor-control PWM
LPC1776 256 80 4 9 18 5 3 3 1 1x FS 2 1 8 ch/12 b 400 ksps 10 b 1 1 16/32 141/165 120 2.4-3.6 -40 to +85 LQFP208, TFBGA180 QEI, motor-control PWM
LPC1777 512 96 4 9 18 5 3 3 1 1x FS 2 8 ch/12 b 400 ksps 10 b 1 1 32 165 120 2.4-3.6 -40 to +85 LQFP208 QEI, motor-control PWM
LPC1778 512 96 4 9 18 5 3 3 1 1x FS 2 1 8 ch/12 b 400 ksps 10 b 1 1 8/16/32 109/165 120 2.4-3.6 -40 to +85 LQFP144/208, TFBGA180/208 QEI, motor-control PWM
LPC1785 256 80 4 9 18 5 3 3 1 1x FS 2 8 ch/12 b 400 ksps 10 b 1 1 1 32 165 120 2.4-3.6 -40 to +85 LQFP208 Motor-control PWM
LPC1786 256 80 4 9 18 5 3 3 1 1x FS 2 1 8 ch/12 b 400 ksps 10 b 1 1 1 32 165 120 2.4-3.6 -40 to +85 LQFP208 QEI, motor-control PWM
LPC1787 512 96 4 9 18 5 3 3 1 1x FS 2 8 ch/12 b 400 ksps 10 b 1 1 1 32 165 120 2.4-3.6 -40 to +85 LQFP208 QEI, motor-control PWM
LPC1788 512 96 4 9 18 5 3 3 1 1x FS 2 1 8 ch/12 b 400 ksps 10 b 1 1 1 8/16/32 109/165 120 2.4-3.6 -40 to +85 LQFP144/208, TFBGA180/208 QEI, motor-control PWM
LPC1700 Series (continued)
LPC1800 Series I Best M3 performance, multi-high-speed connectivity, advanced peripherals I Cortex-M3
These feature-packed devices combine the industry’s highest-performance Cortex-M3 (up to 180 MHz) with a wide range of advanced connectivity.
Part no.
Memory Timers Serial interfaces Analog Security
RTC
LCDcontroller
QuadSPIFlash
interface(SPIFI)6
SDIO
Externalbus
interface(bits)
GPIO
Maxclockspeed
(MHz)
Supplyvoltage(V)
Temperaturerange
(°C)
Package Notes
Flash(kB)
RAM(kB)
EEPROM(kB)
Standardtimers1
PWMchannels2
State-configurable
timer(SCTimer/
PWM)3
UART
I2C
SPI
I2S
USBdevice/host4
CAN
Ethernet
ADCchannels/
resolution
Samplerate
DAC
AESengine
OTPkeystorage5
Truerandomnum-
bergeneratorLPC18xx: High-performance Cortex-M3
LPC1810 136 10 22 1 4 2 3 2 2 2x 8 ch/10 b 400 ksps 10 b 1 1 1 8/16 Up to 64 180 2.2-3.6 -40 to +85 LQFP144, TFBGA100 Flashless
LPC1812 512 104 16 10 22 1 4 2 3 2 2 2x 8 ch/10 b 400 ksps 10 b 1 1 1 8/16 Up to 64 180 2.2-3.6 -40 to +105 LQFP144, TFBGA100 Single-bank Flash
LPC1813 512 104 16 10 22 1 4 2 3 2 2 2x 8 ch/10 b 400 ksps 10 b 1 1 1 8/16 Up to 64 180 2.2-3.6 -40 to +105 LQFP144, TFBGA100 Dual-bank Flash
LPC1815 768 136 16 10 22 1 4 2 3 2 2 2x 8 ch/10 b 400 ksps 10 b 1 1 1 8/16 Up to 64 180 2.2-3.6 -40 to +105 LQFP144, TFBGA100 Dual-bank Flash
LPC1817 1024 136 16 10 22 1 4 2 3 2 2 2x 8 ch/10 b 400 ksps 10 b 1 1 1 8/16 Up to 64 180 2.2-3.6 -40 to +105 LQFP144, TFBGA100 Dual-bank Flash
LPC1820 168 10 22 1 4 2 3 2 1x HS 2 2x 8 ch/10 b 400 ksps 10 b 1 1 1 8/16 Up to 64 180 2.2-3.6 -40 to +85 LQFP144, TFBGA100 Flashless, on-chip HS USB PHY with OTG
LPC1822 512 104 16 10 22 1 4 2 3 2 1x HS 2 2x 8 ch/10 b 400 ksps 10 b 1 1 1 8/16 Up to 64 180 2.2-3.6 -40 to +105 LQFP144, TFBGA100 Single-bank Flash, on-chip HS USB PHY with OTG
LPC1823 512 104 16 10 22 1 4 2 3 2 1x HS 2 2x 8 ch/10 b 400 ksps 10 b 1 1 1 8/16 Up to 64 180 2.2-3.6 -40 to +105 LQFP144, TFBGA100 Dual-bank Flash, on-chip HS USB PHY with OTG
LPC1825 768 136 16 10 22 1 4 2 3 2 1x HS 2 2x 8 ch/10 b 400 ksps 10 b 1 1 1 8/16 Up to 64 180 2.2-3.6 -40 to +105 LQFP144, TFBGA100 Dual-bank Flash, on-chip HS USB PHY with OTG
LPC1827 1024 136 16 10 22 1 4 2 3 2 1x HS 2 2x 8 ch/10 b 400 ksps 10 b 1 1 1 8/16 Up to 64 180 2.2-3.6 -40 to +105 LQFP144, TFBGA100 Dual-bank Flash, on-chip HS USB PHY with OTG
LPC1830 200 10 22 1 4 2 3 2 2x HS6
2 1 2x 8 ch/10 b 400 ksps 10 b 1 1 1 16/32 Up to 64 180 2.2-3.6 -40 to +85
LQFP144, TFBGA100/180,
LBGA256
Flashless, on-chip HS USB PHY with OTG
LPC1833 512 136 16 10 22 1 4 2 3 2 2x HS6
2 1 2x 8 ch/10 b 400 ksps 10 b 1 1 1 16/32 164 180 2.2-3.6 -40 to +105 LQFP100/144, LBGA256 Dual-bank Flash, on-chip HS USB PHY with OTG
LPC1837 1024 136 16 10 22 1 4 2 3 2 2x HS6
2 1 2x 8 ch/10 b 400 ksps 10 b 1 1 1 16/32 164 180 2.2-3.6 -40 to +105 LQFP100/144, LBGA256 Dual-bank Flash, on-chip HS USB PHY with OTG
LPC1850 200 10 22 1 4 2 3 2 2x HS6
2 1 2x 8 ch/10 b 400 ksps 10 b 1 1 1 1 16/32 164 180 2.2-3.6 -40 to +85
LQFP208, TFBGA180,
LBGA256
Flashless, on-chip USB HS PHY with OTG,
1024x768 color LCD controller
LPC1853 512 136 16 10 22 1 4 2 3 2 2x HS6
2 1 2x 8 ch/10 b 400 ksps 10 b 1 1 1 1 16/32 164 180 2.2-3.6 -40 to +105 LQFP208, LBGA256
Dual-bank Flash, on-chip USB HS PHY with OTG,
1024x768 color LCD controller
LPC1857 1024 136 16 10 22 1 4 2 3 2 2x HS6
2 1 2x 8 ch/10 b 400 ksps 10 b 1 1 1 1 16/32 164 180 2.2-3.6 -40 to +105 LQFP208, LBGA256
Dual-bank Flash, on-chip USB HS PHY with OTG,
1024x768 color LCD controller
7. 7
LPC1800 Series (continued)
Part no.
Memory Timers Serial interfaces Analog Security
RTC
LCDcontroller
QuadSPIFlash
interface(SPIFI)6
SDIO
Externalbus
interface(bits)
GPIO
Maxclockspeed
(MHz)
Supplyvoltage(V)
Temperaturerange
(°C)
Package Notes
Flash(kB)
RAM(kB)
EEPROM(kB)
Standardtimers1
PWMchannels2
State-configurable
timer(SCTimer/
PWM)3
UART
I2C
SPI
I2S
USBdevice/host4
CAN
Ethernet
ADCchannels/
resolution
Samplerate
DAC
AESengine
OTPkeystorage5
Truerandomnum-
bergenerator
LPC18Sxx: High-performance Cortex-M3 with security features for protecting code and data
LPC18S10 136 10 22 1 4 2 3 2 2 2 x 8 ch/10b 400 ksps 10 b • • • 1 1 1 8/16 Up to 64 180 2.2-3.6 -40 to +85
LQFP144, BGA100,
BGA180
Flashless
LPC18S30 200 10 22 1 4 2 3 2 2 x HS7
2 1 2 x 8 ch/10b 400 ksps 10 b • • • 1 1 1 16/32 Up to 64 180 2.2-3.6 -40 to +85
LQFP144, BGA100,
BGA256
Flashless, on-chip USB HS PHY with OTG
LPC18S37 1024 136 16 10 22 1 4 2 3 2 2 x HS7
2 1 2 x 8 ch/10b 400 ksps 10 b • • • 1 1 1 16/32 164 180 2.2-3.6 -40 to +105 LQFP144, BGA100 Dual-bank Flash, on-chip USB HS PHY with OTG
LPC18S50 200 10 22 1 4 2 3 2 2 x HS7
2 1 2 x 8 ch/10b 400 ksps 10 b • • • 1 1 1 1 16/32 164 180 2.2-3.6 -40 to +85 BGA180, BGA256 Flashless, on-chip USB HS PHY with OTG
LPC18S57 1024 136 16 10 22 1 4 2 3 2 2 x HS7
2 1 2 x 8 ch/10b 400 ksps 10 b • • • 1 1 1 1 16/32 164 180 2.2-3.6 -40 to +105 LQFP208, BGA256 Dual-bank Flash, on-chip USB HS PHY with OTG
LPC4000 Series I High performance, DSP options, multi-connectivity, advanced peripherals I Cortex-M4/M4F
These Cortex-M4/M4F MCUs provide an upgrade path for the Cortex-M3 LPC177x/8x families.
Part no.
Floating-point
unit(FPU)
Memory Timers Serial interfaces Analog
RTC
LCDcontroller
QuadSPIFlash
Interface(SPIFI)4
SD/MMC
Externalbus
interface(bits)
GPIO
Maxclockspeed
(MHz)
Supplyvoltage(V)
Temperaturerange
(°C)
Package Notes
Flash(kB)
RAM(kB)
EEPROM(kB)
Standardtimers1
PWMchannels2
UART
I2C
SPI
I2S
USBdevice/
host/OTG3
CAN
Ethernet
ADCchannels/
resolution
Samplerate
DAC
Comparator
LPC4072 64 24 2 9 18 4 3 3 1 1x FS 2 8 ch/12 b 400 ksps 10 b 1 1 53 120 2.4-3.6 -40 to +85 LQFP80, TFBGA80 Low-power Harvard architecture
LPC4074 128 40 2 9 18 4 3 3 1 1x FS 2 8 ch/12 b 400 ksps 10 b 1 1 53/109 120 2.4-3.6 -40 to +85 LQFP144, TFBGA80 Low-power Harvard architecture
LPC4076 1 256 80 4 9 18 5 3 3 1 1x FS 2 1 8 ch/12 b 400 ksps 10 b 2 1 1 1 8/16 109/140 120 2.4-3.6 -40 to +85 LQFP144, TFBGA180 Low-power Harvard architecture, QEI, floating-point unit
LPC4078 1 512 96 4 9 18 5 3 3 1 1x FS 2 1 8 ch/12 b 400 ksps 10 b 2 1 1 1 8/16/32 53/165 120 2.4-3.6 -40 to +85
LQFP80/100/144/208,
TFBGA180/208
Low-power Harvard architecture, QEI, floating-point unit
LPC4088 1 512 96 4 9 18 5 3 3 1 1x FS 2 1 8 ch/12 b 400 ksps 10 b 2 1 1 1 1 8/16/32 109/165 120 2.4-3.6 -40 to +85
LQFP144/208,
TFBGA180/208
Low-power Harvard architecture, QEI, floating-point unit
1
Includes Watchdog timer, systick timer, motor-control timer, PWM timer, and real-time clock
2
Using motor-control PWM and two general-purpose PWMs
3
FS = Full Speed
4
SPIFI peripheral enables use of large, low-cost Quad SPI Flash
LPC4300 Series I Best performance, DSP functionality, dual cores, multi-high-speed connectivity, advanced peripherals I Cortex-M4F/M0
These multi-core devices combine the Cortex-M4F’s DSP capabilities with the Cortex-M0’s power efficiency enabling application partition across cores for higher performance.
Part no.
Core Memory Timers Serial interfaces Analog Security
RTC
LCDcontroller
QuadSPIFlash
Interface(SPIFI)7
SDIO
Externalbus
interface(bits)
GPIO
Maxclockspeed
(MHz)
Supplyvoltage(V)
Temperaturerange
(°C)
Package Notes
M0coprocessor
Flash(kB)
RAM(kB)
EEPROM(kB)
Standardtimers1
PWMchannels2
State-configurable
timer(SCTimer/
PWM)3
UART
I2C
SPI
I2S
SGPIO4
USBdevice/
host5
CAN
Ethernet
ADCchannels/
resolution
Samplerate
DAC
AESengine
OTPkeystorage6
Truerandomnum-
bergenerator
LPC43xx: Multi-core Cortex-M4F/M0
LPC4310 1 168 12 22 1 4 2 3 2 1 2 2 x 4/6 ch/10 b 400 ksps 10 b 1 1 1 8/16 Up to 83 204 2.2-3.6 -40 to +85 LQFP144, TFBGA100 Flashless
LPC4312 1 512 104 16 12 22 1 4 2 3 2 1 2 2 x 4/6 ch/10 b 400 ksps 10 b 1 1 1 8/16 Up to 83 204 2.2-3.6 -40 to +105 LQFP144, TFBGA100 Single-bank Flash
LPC4313 1 512 104 16 12 22 1 4 2 3 2 1 2 2 x 4/6 ch/10 b 400 ksps 10 b 1 1 1 8/16 Up to 83 204 2.2-3.6 -40 to +105 LQFP144, TFBGA100 Dual-bank Flash
LPC4315 1 768 136 16 12 22 1 4 2 3 2 1 2 2 x 4/6 ch/10 b 400 ksps 10 b 1 1 1 8/16 Up to 83 204 2.2-3.6 -40 to +105 LQFP144, TFBGA100 Dual-bank Flash
LPC4317 1 1024 136 16 12 22 1 4 2 3 2 1 2 2 x 4/6 ch/10 b 400 ksps 10 b 1 1 1 8/16 Up to 83 204 2.2-3.6 -40 to +105 LQFP144, TFBGA100 Dual-bank Flash
LPC4320 1 200 12 22 1 4 2 3 2 1 1x HS 2 2 x 4/6 ch/10 b 400 ksps 10 b 1 1 1 8/16 Up to 83 204 2.2-3.6 -40 to +85 LQFP144, TFBGA100 Flashless, on-chip USB HS PHY
LPC4322 1 512 104 16 12 22 1 4 2 3 2 1 1x HS 2 2 x 4/6 ch/10 b 400 ksps 10 b 1 1 1 8/16 Up to 83 204 2.2-3.6 -40 to +105 LQFP144, TFBGA100 Single-bank Flash, on-chip USB HS PHY
LPC4323 1 512 104 16 12 22 1 4 2 3 2 1 1x HS 2 2 x 4/6 ch/10 b 400 ksps 10 b 1 1 1 8/16 Up to 83 204 2.2-3.6 -40 to +105 LQFP144, TFBGA100 Dual-bank Flash, on-chip USB HS PHY
www.nxp.com/microcontrollers
1
Includes Watchdog timer, real-time alarm clock, repetitive-interrupt timer,
systick timer, and SCTimer/PWM configured as two 16-bit timers
2
Using motor-control PWM and SCTimer/PWM as PWM
3
SCTimer/PWM peripheral can be configured as additional timers and/or PWM channels
4
HS = High Speed
5
OTP can store two 128-bit keys
6
SPIFI peripheral enables use of large, low-cost Quad SPI Flash
7
USB0 = integrated HS PHY, USB1 = integrated FS PHY or ULPI
8. 8
ARM7 and ARM9 Cores
Building on some of the industry’s most popular ARM®
cores, these devices deliver tailored performance in a very wide range of applications. Many are pin-
compatible with LPC Cortex-M families, providing fast development with easy design scalability.
LPC2100/200/300/400 Series I The most popular ARM7 I ARM7TDMI-S
These ARM7 MCUs are some of the industry’s most popular 32-bit MCUs for control applications.
Part no.
Memory Timers Serial interfaces Analog
RTC
LCDcontroller
SD/MMC
Externalbus
interface(bits)
GPIO
Maxclockspeed
(MHz)
Supplyvoltage(V)
Temperaturerange
(°C)
Package Notes
Flash(kB)
RAM(kB)
EEPROM(kB)
Standardtimers1
PWMchannels2
UART
I2C
SPI
I2S
USBdevice/
host/OTG3
CAN
Ethernet
ADCchannels/
resolution
Samplerate
DAC
LPC21xx
LPC2101 8 2 6 14 2 2 2 8 ch/10 b 400 ksps 1 32 70 1.8/3.3 -40 to +85 LQFP48 Dual supply voltage, 32 kHz XTAL input, fast I/O
LPC2102 16 4 6 14 2 2 2 8 ch/10 b 400 ksps 1 32 70 1.8/3.3 -40 to +85 LQFP48 Dual supply voltage, 32 kHz XTAL input, fast I/O
LPC2103 32 8 6 14 2 2 2 8 ch/10 b 400 ksps 1 32 70 1.8/3.3 -40 to +85 LQFP48 Dual supply voltage, 32 kHz XTAL input, fast I/O
LPC2104 128 16 5 6 2 1 1 1 32 60 1.8/3.3 -40 to +85 LQFP48 Dual supply voltage, 32 kHz XTAL input, fast I/O
LPC2106 128 64 5 6 2 1 1 1 32 60 1.8/3.3 -40 to +85 LQFP48 Dual supply voltage, 32 kHz XTAL input, fast I/O
www.nxp.com/microcontrollers
LPC4300 Series (continued)
Part no.
Core Memory Timers Serial interfaces Analog Security
RTC
LCDcontroller
QuadSPIFlash
Interface(SPIFI)7
SDIO
Externalbus
interface(bits)
GPIO
Maxclockspeed
(MHz)
Supplyvoltage(V)
Temperaturerange
(°C)
Package Notes
M0coprocessor
Flash(kB)
RAM(kB)
EEPROM(kB)
Standardtimers1
PWMchannels2
State-configurable
timer(SCTimer/
PWM)3
UART
I2C
SPI
I2S
SGPIO4
USBdevice/
host5
CAN
Ethernet
ADCchannels/
resolution
Samplerate
DAC
AESengine
OTPkeystorage6
Truerandomnum-
bergenerator
LPC4325 1 768 136 16 12 22 1 4 2 3 2 1 1x HS 2 2 x 4/6 ch/10 b 400 ksps 10 b 1 1 1 8/16 Up to 83 204 2.2-3.6 -40 to +105 LQFP144, TFBGA100 Dual-bank Flash, on-chip USB HS PHY
LPC4327 1 1024 136 16 12 22 1 4 2 3 2 1 1x HS 2 2 x 4/6 ch/10 b 400 ksps 10 b 1 1 1 8/16 Up to 83 204 2.2-3.6 -40 to +105 LQFP144, TFBGA100 Dual-bank Flash, on-chip USB HS PHY
LPC4330 1 264 12 22 1 4 2 3 2 1 2x HS8
2 1 2 x 8 ch/10 b 400 ksps 10 b 1 1 1 16/32 Up to 164 204 2.2-3.6 -40 to +85
LQFP144, TFBGA180/
100, LBGA256
Flashless, on-chip USB HS PHY with OTG
LPC4333 1 512 136 16 12 22 1 4 2 3 2 1 2x HS8
2 1 2 x 8 ch/10 b 400 ksps 10 b 1 1 1 16/32 Up to 164 204 2.2-3.6 -40 to +105
LQFP144, TFBGA100,
LBGA256
Dual-bank Flash, on-chip HS USB PHY
LPC4337 1 1024 136 16 12 22 1 4 2 3 2 1 2x HS8
2 1 2 x 8 ch/10 b 400 ksps 10 b 1 1 1 16/32 Up to 164 204 2.2-3.6 -40 to +105
LQFP144, TFBGA100,
LBGA256
Dual-bank Flash, on-chip HS USB PHY
with OTG
LPC4350 1 264 12 22 1 4 2 3 2 1 2x HS8
2 1 2 x 8 ch/10 b 400 ksps 10 b 1 1 1 1 16/32 Up to 164 204 2.2-3.6 -40 to +85
LQFP208, LBGA256,
TFBGA180
Flashless, on-chip HS USB PHY,
1024x768 color LCD controller
LPC4353 1 512 136 16 12 22 1 4 2 3 2 1 2x HS8
2 1 2 x 8 ch/10 b 400 ksps 10 b 1 1 1 1 16/32 Up to 164 204 2.2-3.6 -40 to +105 LQFP208, LBGA256
Dual-bank Flash, on-chip HS USB PHY,
1024x768 color LCD controller
LPC4357 1 1024 136 16 12 22 1 4 2 3 2 1 2x HS8
2 1 2 x 8 ch/10 b 400 ksps 10 b 1 1 1 1 16/32 Up to 164 204 2.2-3.6 -40 to +105 LQFP208, LBGA256
Dual-bank Flash, on-chip HS USB PHY,
1024x768 color LCD controller
LPC4370 2 282 12 22 1 4 2 3 2 1 2x HS8
2 1
1 x 6 ch/12 b 80 Msps
10 b 1 1 1 1 8/32 Up to 164 204 2.2-3.6 -40 to +85 LBGA256, TFBGA100
6 ch 80 Msps ADC, on-chip USB PHY,
1024x768 color LCD controller2 x 8 ch/10 b9
400 ksps
LPC43Sxx: Multi-core Cortex-M4F/M0 with security features for protecting code and data
LPC43S20 1 200 12 22 1 4 2 3 2 1 1x HS 2 2 x 4/6 ch/10 b 400 ksps 10 b • • • 1 1 1 8/16 Up to 83 204 2.2-3.6 -40 to +85 LQFP144,BGA180 Flashless, on-chip USB HS PHY
LPC43S30 1 264 12 22 1 4 2 3 2 1 2x HS8
2 1 2 x 8 ch/10 b 400 ksps 10 b • • • 1 1 1 16/32 Up to 164 204 2.2-3.6 -40 to +85
LQFP144, BGA100,
BGA256
Flashless, on-chip USB HS PHY with OTG
LPC43S37 1 1024 136 16 12 22 1 4 2 3 2 1 2x HS8
2 1 2 x 8 ch/10 b 400 ksps 10 b • • • 1 1 1 16/32 Up to 164 204 2.2-3.6 -40 to +105 LQFP144,BGA100
Dual-bank Flash, on-chip USB HS PHY
with OTG
LPC43S50 1 264 12 22 1 4 2 3 2 1 2x HS8
2 1 2 x 8 ch/10 b 400 ksps 10 b • • • 1 1 1 1
Flashless, on-chip USB HS PHY
1024x768 color LCD controller
LPC43S57 1 1024 136 16 12 22 1 4 2 3 2 1 2x HS8
2 1 2 x 8 ch/10 b 400 ksps 10 b • • • 1 1 1 1 16/32 Up to 164 204 2.2-3.6 -40 to +85 BGA180, BGA256
Dual-bank Flash, on-chip USB HS PHY
1024x768 color LCD controller
LPC43S70 2 282 12 22 1 4 2 3 2 1 2x HS8
2 1
1 x 6 ch/12 b 80 Msps
10 b • • • 1 1 1 1 16/32 Up to 164 204 2.2-3.6 -40 to +85 BGA100, BGA256
6 ch 80 Msps ADC, on-chip USB PHY,
1024x768 color LCD controller2 x 8 ch/10 b9
400 ksps
1
Includes Watchdog timer, real-time alarm clock, repetitive-interrupt timer, systick
timer, and SCTimer/PWM configured as two 16-bit timers
2
Using motor-control PWM and SCTimer/PWM as PWM
3
SCTimer/PWM peripheral can be configured as additional timers and/or PWM channels
4
SGPIO peripheral can be configured as additional PWM, I2
C, I2
S, SSI/SSP, and/or UART channels
5
HS = Hi-Speed
6
OTP can store two 128-bit keys
7
SPIFI peripheral enables use of large, low-cost Quad SPI Flash
8
USB0 = integrated HS PHY, USB1 = integrated FS PHY or ULPI
9
LBGA256 package only
9. 9
LPC2100/200/300/400 Series (continued)
Part no.
Memory Timers Serial interfaces Analog
RTC
LCDcontroller
SD/MMC
Externalbus
interface(bits)
GPIO
Maxclockspeed
(MHz)
Supplyvoltage(V)
Temperaturerange
(°C)
Package Notes
Flash(kB)
RAM(kB)
EEPROM(kB)
Standardtimers1
PWMchannels2
UART
I2C
SPI
I2S
USBdevice/
host/OTG3
CAN
Ethernet
ADCchannels/
resolution
Samplerate
DAC
LPC2131 32 8 5 6 2 2 2 8 ch/10 b 400 ksps 1 47 60 3.0-3.6 -40 to +85 LQFP64 Brownout detection, power-on reset, 32 kHz XTAL input, VBAT, fast I/O
LPC2132 64 16 5 6 2 2 2 8 ch/10 b 400 ksps 10 b 1 47 60 3.0-3.6 -40 to +85 LQFP64 Brownout detection, power-on reset, 32 kHz XTAL input, VBAT, fast I/O
LPC2134 128 16 5 6 2 2 2 2x 8 ch/10 b 400 ksps 10 b 1 47 60 3.0-3.6 -40 to +85 LQFP64 Brownout detection, power-on reset, 32 kHz XTAL input, VBAT, fast I/O
LPC2136 256 32 5 6 2 2 2 2x 8 ch/10 b 400 ksps 10 b 1 47 60 3.0-3.6 -40 to +85 LQFP64 Brownout detection, power-on reset, 32 kHz XTAL input, VBAT, fast I/O
LPC2138 512 32 5 6 2 2 2 2x 8 ch/10 b 400 ksps 10 b 1 47 60 3.0-3.6 -40 to +85
LQFP64,
HVQFN64
Brownout detection, power-on reset, 32 kHz XTAL input, VBAT, fast I/O
LPC2141 32 8 5 6 2 2 2 1x FS 6 ch/10 b 400 ksps 1 45 60 3.0-3.6 -40 to +85 LQFP64 Brownout detection, power-on reset, 32 kHz XTAL input, VGA, fast I/O
LPC2142 64 16 5 6 2 2 2 1x FS 6 ch/10 b 400 ksps 10 b 1 45 60 3.0-3.6 -40 to +85 LQFP64 Brownout detection, power-on reset, 32 kHz XTAL input, VGA, fast I/O
LPC2144 128 16 5 6 2 2 2 1x FS
1x 6 ch/10 b
1x 8 ch/10 b
400 ksps 10 b 1 45 60 3.0-3.6 -40 to +85 LQFP64 Brownout detection, power-on reset, 32 kHz XTAL input, VGA, fast I/O
LPC2146 256 40 5 6 2 2 2 1x FS
1x 6 ch/10 b
1x 8 ch/10 b
400 ksps 10 b 1 45 60 3.0-3.6 -40 to +85 LQFP64 Brownout detection, power-on reset, 32 kHz XTAL input, VGA, fast I/O
LPC2148 512 40 5 6 2 2 2 1x FS
1x 6 ch/10 b
1x 8 ch/10 b
400 ksps 10 b 1 45 60 3.0-3.6 -40 to +85 LQFP64 Brownout detection, power-on reset, 32 kHz XTAL input, VGA, fast I/O
LPC22xx
LPC2210 16 3 6 2 1 2 8 ch/10 b 400 ksps 1 76 60 1.8/3.3 -40 to +85 LQFP144 Dual supply voltage, 32 kHz XTAL input, fast I/O
LPC2212 128 16 3 6 2 1 2 8 ch/10 b 400 ksps 1 112 60 1.8/3.3 -40 to +85 LQFP144 Dual supply voltage, 32 kHz XTAL input, fast I/O
LPC2214 256 16 3 6 2 1 2 8 ch/10 b 400 ksps 1 112 60 1.8/3.3 -40 to +85 LQFP144 Dual supply voltage, 32 kHz XTAL input, fast I/O
LPC2220 64 3 6 2 1 2 8 ch/10 b 400 ksps 1 76 75 1.8/3.3 -40 to +85
LQFP144,
TFBGA144
Dual supply voltage, 32 kHz XTAL input, fast I/O
LPC2290 64 3 6 2 1 2 2 8 ch/10 b 400 ksps 1 76 60 1.8/3.3 -40 to +85 LQFP144 Dual supply voltage, 32 kHz XTAL input, fast I/O
LPC2292 256 16 3 6 2 1 2 2 8 ch/10 b 400 ksps 1 112 60 1.8/3.3 -40 to +85
LQFP144,
TFBGA144
Dual supply voltage, 32 kHz XTAL input, fast I/O
LPC2294 256 16 3 6 2 1 2 4 8 ch/10 b 400 ksps 1 112 60 1.8/3.3 -40 to +125 LQFP144 Dual supply voltage, 32 kHz XTAL input, fast I/O
LPC23xx
LPC2361 64 34 6 6 4 3 3 1 1x FS 2 6 ch/10 b 400 ksps 10 b 1 70 72 3.0-3.6 -40 to +85 LQFP100 On-chip USB PHY, RC oscillator, DMA, RTC, IrDA
LPC2362 128 58 6 6 4 3 3 1 1x FS 2 1 6 ch/10 b 400 ksps 10 b 1 70 72 3.0-3.6 -40 to +85 LQFP100 On-chip USB PHY, RC oscillator, DMA, RTC, IrDA
LPC2364 128 34 6 6 4 3 3 1 1x FS 2 1 6 ch/10 b 400 ksps 10 b 1 70 72 3.0-3.6 -40 to +85
LQFP100,
TFBGA100
On-chip USB PHY, DMA, RTC, IrDA
LPC2365 256 58 6 6 4 3 3 1 1 6 ch/10 b 400 ksps 10 b 1 70 72 3.0-3.6 -40 to +85 LQFP100 RC oscillator, DMA, RTC, IrDA
LPC2366 256 58 6 6 4 3 3 1 1x FS 2 1 6 ch/10 b 400 ksps 10 b 1 70 72 3.0-3.6 -40 to +85 LQFP100 On-chip USB PHY, RC oscillator, DMA, RTC, IrDA
LPC2367 512 58 6 6 4 3 3 1 1 6 ch/10 b 400 ksps 10 b 1 1 70 72 3.0-3.6 -40 to +85 LQFP100 RC oscillator, DMA, RTC, IrDA
LPC2368 512 58 6 6 4 3 3 1 1x FS 2 1 6 ch/10 b 400 ksps 10 b 1 1 70 72 3.0-3.6 -40 to +85
LQFP100,
TFBGA100
On-chip USB PHY, RC oscillator, DMA, RTC, IrDA
LPC2377 512 58 6 6 4 3 3 1 1 8 ch/10 b 400 ksps 10 b 1 1 8 104 72 3.0-3.6 -40 to +85 LQFP144 RC oscillator, DMA, RTC, IrDA, 8-bit Mini-Bus
LPC2378 512 58 6 6 4 3 3 1 1x FS 2 1 8 ch/10 b 400 ksps 10 b 1 1 8 104 72 3.0-3.6 -40 to +85 LQFP144 On-chip USB PHY, RC oscillator, DMA, RTC, IrDA, 8-bit Mini-Bus
LPC2387 512 98 6 6 4 3 3 1 1x FS 2 1 8 ch/10 b 400 ksps 10 b 1 1 70 72 3.0-3.6 -40 to +85 LQFP100 On-chip USB PHY, RC oscillator, DMA, RTC, IrDA
LPC2388 512 98 6 6 4 3 3 1 1x FS 2 1 8 ch/10 b 400 ksps 10 b 1 1 8 104 72 3.0-3.6 -40 to +85 LQFP144 On-chip USB PHY, RC oscillator, DMA, RTC, IrDA, 8-bit Mini-Bus
LPC24xx
LPC2420 82 6 12 4 3 2 1 2x FS 8 ch/10 b 400 ksps 10 b 1 1 32 160 72 3.0-3.6 -40 to +85
LQFP208,
TFBGA208
On-chip USB PHY, RC oscillator, DMA, RTC, 2 PWM blocks, IrDA
LPC2458 512 98 6 12 4 3 2 1 2x FS 2 1 8 ch/10 b 400 ksps 10 b 1 1 16 160 72 3.0-3.6 -40 to +85 TFBGA180 On-chip USB PHY, RC oscillator, DMA, RTC, 2 PWM blocks, IrDA
LPC2460 98 6 12 4 3 2 1 2x FS 2 1 8 ch/10 b 400 ksps 10 b 1 1 32 160 72 3.0-3.6 -40 to +85
LQFP208,
TFBGA208
On-chip USB PHY, RC oscillator, DMA, RTC, 2 PWM blocks, IrDA
LPC2468 512 98 6 12 4 3 2 1 2x FS 2 1 8 ch/10 b 400 ksps 10 b 1 1 32 160 72 3.0-3.6 -40 to +85
LQFP208,
TFBGA208
On-chip USB PHY, RC oscillator, DMA, RTC, 2 PWM blocks, IrDA
LPC2470 98 6 12 4 3 2 1 2x FS 2 1 8 ch/10 b 400 ksps 10 b 1 1 1 32 160 72 3.0-3.6 -40 to +85
LQFP208,
TFBGA208
On-chip USB PHY, RC oscillator, DMA, RTC, 2 PWM blocks, IrDA
LPC2478 512 98 6 12 4 3 2 1 2x FS 2 1 8 ch/10 b 400 ksps 10 b 1 1 1 32 160 72 3.0-3.6 -40 to +85
LQFP208,
TFBGA208
On-chip USB PHY, RC oscillator, DMA, RTC, 2 PWM blocks, IrDA
1
Includes Watchdog timer and real-time clock
2
Using timers 0-3
3
FS = Full Speed
www.nxp.com/microcontrollers
10. 10www.nxp.com/microcontrollers
LPC3000 Series I Linux platforms I ARM926EJ
An ideal, low-cost platform for running the Linux operating system, these high-performance ARM9-based application controllers operate at clock speeds up to 270 MHz.
Part no.
Memory Timers Serial interfaces Analog
RTC
LCDcontroller
SD/MMC
Externalbus
interface(bits)
GPIO
Maxclockspeed
(MHz)
Supplyvoltage(V)
Temperaturerange
(°C)
Package Notes
RAM(kB)
Standardtimers
PWMchannels
UART
I2C
SPI
I2S
USBdevice/
host/OTG1
CAN
Ethernet
ADCchannels/
resolution
Samplerate
LPC31xx: ARM926EJ with NAND Flash controller
LPC3130 96 4 1 1 2 4 2 1x HS 4 ch/10 b 400 ksps 1 1 1 32 97 180 1.8-3.3 -40 to +85 TFBGA180 Random number generator
LPC3131 192 4 1 1 2 4 2 1x HS 4 ch/10 b 400 ksps 1 1 1 16 97 180 1.8-3.3 -40 to +85 TFBGA180 Random number generator
LPC3143 192 4 1 1 2 4 2 1x HS 4 ch/10 b 400 ksps 1 1 1 16 97 270 1.8-3.3 -40 to +85 TFBGA180
Random number generator, unique ID, OTP, decryption engine,
secure boot
LPC3154 192 4 1 1 1 3 2 1x HS 3 ch/10 b 400 ksps 1 1 1 32 157 180 1.8-3.3 -40 to +85 TFBGA208 LPC3152 with decryption, secure boot
LPC3180/01 64 4 1 7 2 3 1x FS 3 ch/10 b 400 ksps 1 1 32 55 208 1.8-3.3 -40 to +85 LFBGA320 Low power, VFP unit, NAND Flash, SDRAM/DDR
LPC32xx: ARM926EJ with VFP coprocessor
LPC3220 128 8 11 7 2 2 2 1x FS 2 3 ch/10 b 400 ksps 1 1 32 87 266 1.8-3.3 -40 to +85 LFBGA296 Low-power mode (0.9 V), SDRAM/DDR, keypad interface
LPC3240 256 8 11 7 2 2 2 1x FS 2 1 3 ch/10 b 400 ksps 1 1 32 87 266 1.8-3.3 -40 to +85 LFBGA296 Low-power mode (0.9 V), SDRAM/DDR, keypad interface
LPC3250 256 8 11 7 2 2 2 1x FS 2 1 3 ch/10 b 400 ksps 1 1 1 32 87 266 1.8-3.3 -40 to +85 LFBGA296
Low-power mode (0.9 V), SDRAM/DDR, keypad interface, 24-bit
color LCD/touchscreen controller
1
FS = Full Speed, HS = High Speed
LPC2900 Series I Fastest ARM986 I ARM986E-S
The LPC2900 Series microcontrollers are an excellent choice for demanding applications like industrial drives, HVAC systems, vending and cash machines, and motor control.
Part no.
Memory Timers Serial interfaces Analog
Externalbus
interface(bits)
GPIO
Maxclockspeed
(MHz)
Supplyvoltage(V)
Temperaturerange
(°C)
Package Notes
Flash(kB)
RAM(kB)
EEPROM(kB)
Standardtimers1
PWMchannels2
UART
I2C
SPI
USBdevice/
host/OTG3
CAN
ADCchannels/
resolution
Samplerate
LPC2900: ARM968E-S
LPC2925 512 40 16 7 24 4 2 3 1x FS 2 16 ch/10 b 400 ksps 60 125 1.8/3.3 -40 to +85 LQFP100 Dual supply, USB device/OTG controller, 32 k I- & D-TCM, motor control, GP DMA
LPC2926 256 56 16 7 24 4 2 3 1x FS 2 24 ch/10 b 400 ksps 104 125 1.8/3.3 -40 to +85 LQFP144 Dual supply, USB device/OTG controller, 32 k I- & D-TCM, motor control, GP DMA
LPC2929 768 56 16 7 24 4 2 3 1x FS 2 24 ch/10 b 400 ksps 8 104 125 1.8/3.3 -40 to +85 LQFP144 Dual supply, USB device/OTG controller, 32 k I- & D-TCM, motor control, GP DMA
LPC2930 56 16 7 24 4 2 3 2x FS 2 24 ch/10 b 400 ksps 32 152 125 1.8/3.3 -40 to +85 LQFP208 Dual supply, USB device/host/OTG controller, 32 k I- & D-TCM, motor control, GP DMA
LPC2939 768 56 16 7 24 4 2 3 2x FS 2 24 ch/10 b 400 ksps 32 152 125 1.8/3.3 -40 to +85 LQFP208 Dual supply, USB device/host/OTG controller, 32 k I- & D-TCM, motor control, GP DMA
1
Includes Watchdog timer and real-time clock
2
Using timers 0-3
3
FS = Full Speed
11. 11
Just one Cortex-M toolchain
All LPC Cortex-M devices work with a single MCU toolchain, so you can move up or down the performance scale without changing tools.
A whole universe of third-party tools and software
NXP brings together world-class development platforms, tools, boards, and software from NXP and partners to get you started developing on NXP LPC microcontrollers in just minutes.
With advanced yet low-cost ways to evaluate, develop, and debug with LPC MCUs and a choice of toolchains that support the entire Cortex-M portfolio, the LPC developer ecosystem
gives you a familiar set of tools no matter which LPC MCU you choose. NXP works closely with the best software product providers in the industry to facilitate the highest quality
middleware for LPC MCUs. Review the current partners and get more details on their products and capabilities at nxp.com/microcontrollers/ecosystem.
The 10-year promise: the NXP Product Longevity program
NXP’s Product Longevity program ensures a stable supply of microcontrollers for your design. Longevity products are available for a minimum of ten years after product launch, and are
supported by our standard end-of-life notification policy. Most products in the Cortex-M and ARM9 categories are covered by the program. Longevity products remain in the program
even if the manufacturing site changes. We manufacture through a number of resources, including our own factories and qualified outside vendors. If we transfer a longevity product to
another facility, we re-qualify the product to maintain its status in the longevity program. For a complete, up-to-date list of longevity products, visit www.nxp.com/microcontrollers.
Discover
the difference
LPCXpresso IDE is our easy-to-use, highly integrated software development environment and includes all the tools necessary to develop high-quality software solutions
in a timely and cost effective fashion. Available as a free download, the LPCXpresso IDE uses Eclipse as its foundation adding a long list of enhancements that empowers
engineers and simplifies development with NXP LPC microcontrollers. It also features the industry-standard GNU toolchain, with a choice of a proprietary optimized C library
or the standard Newlib library. For larger and more complex designs, developers can opt for LPCXpresso IDE Pro Edition, which adds a range of enhanced debugging and
analysis features, plus unlimited code size.
LPCOpen is an extensive set of RTOS-agnostic libraries with common APIs that include chip- and board-level device drivers, protocol stacks for TCP/IP (LwIP), USB devices
and hosts, CAN bus, and two graphics libraries (SWIM and SEGGER emWin). Project files for Keil, IAR, and LPCXpresso toolchains are provided and other toolchains can also
be used if desired.
www.nxp.com/microcontrollers