Embedded - Microcontrollers

Part Number	Description / PDF	Quantity
AS83C196EA Intel	16-BIT, MROM, 8096 CPU, 40MHZ	960
NG88C196EC40 Intel	EMBEDDED 196 PROCESSOR	92509
5962-8998202YA Intel	MICROCONTROLLER, 8096 CPU	6
A8028610 Intel	MCU, 16 BIT, 10MHZ	988
A8028612 Intel	MCU, 16 BIT, 12.5MHZ	193
MG8097BH Intel	16-BIT, 8096 CPU, 12MHZ, MOS	2997
TQ80486DX250 Intel	80486 MICROCONTROLLER, X86 ARCH.	0
WL80960JS2516 Intel	80960 MCU	0
SIXP220A Intel	DSL NETWORK PROCESSOR	4800
N89C026LT Intel	MODEM MICROCONTROLLER	1048
EV80X186EC Intel	EV80X186EC	0
MQ8797BH Intel	16-BIT, UVPROM, 8096 CPU, 12MHZ	401
MR8751H8 Intel	8-BIT, UVPROM, 8051 CPU, 8MHZ	58
EE80C31BH2424 Intel	MCU 8 BIT MCS51 80C51 CISC ROMLE	343
UG80960HD6616 Intel	RISC MICROCONTROLLER, 32BIT, I96	768
MR87C51FB16 Intel	8-BIT UVPROM	1003
UG80960HD8016 Intel	RISC MICROCONTROLLER, 32BIT, I96	968
5962-9069203QYA Intel	MICROCONTROLLER, 8096 CPU	133
UG80960HA4016 Intel	RISC MICROCONTROLLER, 32BIT, I96	0
AS87C196ENF8 Intel	MICROCONTROLLER, 16 BIT, MCS96 C	1920

Embedded - Microcontrollers

1. Overview

Embedded microcontrollers (MCUs) are compact integrated circuits designed to control specific functions in embedded systems. They combine processing cores, memory, and peripheral interfaces into a single chip, enabling efficient control in applications ranging from consumer electronics to industrial automation. Their importance lies in enabling smart, connected, and autonomous systems in modern technology ecosystems.

2. Main Types and Functional Classification

Type	Functional Characteristics	Application Examples
General-Purpose MCUs	Balanced performance, basic peripherals (timers, UART)	Home appliances, simple sensors
Low-Power MCUs	Optimized for energy efficiency, sleep modes	Wearable devices, IoT edge nodes
High-Performance MCUs	32/64-bit cores, DSP capabilities, high-speed interfaces	Industrial automation, automotive systems
Automotive MCUs	ISO 26262 certified, extended temperature range	Engine control units, ADAS

3. Structure and Components

Typical microcontroller architecture includes:

CPU core (e.g., ARM Cortex-M, RISC-V)
Memory (Flash, SRAM, EEPROM)
Peripherals (GPIO, SPI, I2C, ADC/DAC)
Real-time clock (RTC)
Power management unit
Communication interfaces (CAN, Ethernet, USB)

Physical packaging ranges from 8-pin DIP to 200+ pin BGA for complex applications.

4. Key Technical Specifications

Parameter	Description
Clock Speed	Determines processing capability (1 MHz - 1 GHz)
Memory Size	Flash (code storage) and RAM (data processing)
Power Consumption	Active/current sleep mode current draw
I/O Lines	Number and type of programmable GPIO
Operating Temperature	Industrial (-40 C to 85 C) or automotive (-40 C to 125 C)

5. Application Areas

Consumer Electronics: Smart home devices, wearables
Industrial: Motor control, factory automation
Automotive: Body control modules, EV battery management
Medical: Portable diagnostic equipment, infusion pumps
IoT: Wireless sensor networks, edge AI nodes

6. Leading Manufacturers and Products

Manufacturer	Headquarters	Representative Products
Texas Instruments	USA	MSP430FR5994 (low-power sensing)
STMicroelectronics	Switzerland	STM32H7 (high-performance)
Microchip Technology	USA	PIC32MZ (32-bit general purpose)
NXP Semiconductors	Netherlands	Kinetis K82 (automotive-grade)
Infineon Technologies	Germany	Traveo S6J3 (automotive graphics)

7. Selection Recommendations

Key considerations:

Match core architecture to computational needs
Verify peripheral compatibility with sensors/actuators
Check temperature/ruggedness ratings
Evaluate software ecosystem (RTOS support, middleware)
Consider long-term supply stability

Example: For a battery-powered IoT sensor node, prioritize ultra-low power MCUs like the EFR32MG21 with integrated wireless capabilities.

8. Industry Trends

Integration of AI acceleration (e.g., Arm Ethos-U NPU)
Edge computing focus with on-chip machine learning
Enhanced security features (TrustZone, secure boot)
Sub-1V operation for energy harvesting applications
Growth of heterogeneous multi-core MCUs