S9KEAZN64AMLC

Product Overview

Use

This microcontroller is designed for various embedded applications, including but not limited to consumer electronics, industrial automation, and automotive systems.

Characteristics

High-performance 32-bit ARM Cortex-M0+ core
Flash memory for program storage
RAM for data storage
Multiple communication interfaces (UART, SPI, I2C)
Analog-to-digital converters (ADC)
Timers and PWM channels for precise timing control
Low power consumption
Small form factor

Package

The S9KEAZN64AMLC comes in a compact surface-mount package, making it suitable for space-constrained designs.

Essence

The essence of this microcontroller lies in its ability to provide a powerful processing platform with low power consumption, enabling efficient and reliable operation in various applications.

Packaging/Quantity

The S9KEAZN64AMLC is typically packaged in reels or trays, with quantities varying based on customer requirements.

Specifications

Microcontroller Family: S9KEA
Core Architecture: ARM Cortex-M0+
Flash Memory: 64 KB
RAM: 4 KB
Operating Voltage: 1.8V - 3.6V
Operating Temperature Range: -40°C to +85°C
Communication Interfaces: UART, SPI, I2C
Analog-to-Digital Converters: 12-bit, 8 channels
Timers: 16-bit, 4 channels
PWM Channels: 4
GPIO Pins: 48
Package Type: LQFP
Package Dimensions: 7mm x 7mm

Detailed Pin Configuration

The S9KEAZN64AMLC microcontroller has a total of 48 GPIO pins, which can be configured for various purposes such as input, output, or alternate functions. The pin configuration is as follows:

(Pin Number) - (Pin Name) 1 - PTB0 2 - PTB1 3 - PTB2 4 - PTB3 5 - PTB4 6 - PTB5 7 - PTB6 8 - PTB7 9 - PTC0 10 - PTC1 11 - PTC2 12 - PTC3 13 - PTC4 14 - PTC5 15 - PTC6 16 - PTC7 17 - PTD0 18 - PTD1 19 - PTD2 20 - PTD3 21 - PTD4 22 - PTD5 23 - PTD6 24 - PTD7 25 - PTE0 26 - PTE1 27 - PTE2 28 - PTE3 29 - PTE4 30 - PTE5 31 - PTE6 32 - PTE7 33 - PTF0 34 - PTF1 35 - PTF2 36 - PTF3 37 - PTF4 38 - PTF5 39 - PTF6 40 - PTF7 41 - PTG0 42 - PTG1 43 - PTG2 44 - PTG3 45 - PTG4 46 - PTG5 47 - PTG6 48 - PTG7

Functional Features

High-performance processing capabilities
Low power consumption for energy-efficient operation
Flexible communication interfaces for seamless connectivity
Analog-to-digital converters for precise measurement and control
Timers and PWM channels for accurate timing and signal generation
Abundant GPIO pins for versatile input/output configurations
Robust package design for reliable operation in harsh environments

Advantages and Disadvantages

Advantages

Powerful processing capabilities enable efficient execution of complex tasks.
Low power consumption extends battery life in portable applications.
Versatile communication interfaces facilitate seamless integration with other devices.
Abundant GPIO pins provide flexibility in system design.
Compact package size allows for space-constrained designs.

Disadvantages

Limited memory capacity may restrict the size of programs that can be executed.
Lack of built-in peripherals may require additional external components for certain applications.
Higher cost compared to lower-end microcontrollers with fewer features.

Working Principles

The S9KEAZN64AMLC microcontroller operates based on the ARM Cortex-M0+ core architecture. It executes instructions stored in its flash memory, processes data using its internal RAM, and interacts with the external world through various communication interfaces and peripherals. The microcontroller's working principle involves fetching, decoding, and executing instructions to perform specific tasks as programmed by the user.

Detailed Application Field Plans

The S9KEAZN64AMLC

技術ソリューションにおける S9KEAZN64AMLC の適用に関連する 10 件の一般的な質問と回答をリストします。

Sure! Here are 10 common questions and answers related to the application of S9KEAZN64AMLC in technical solutions:

Q: What is the S9KEAZN64AMLC microcontroller used for? A: The S9KEAZN64AMLC microcontroller is commonly used in various technical solutions, such as industrial control systems, consumer electronics, and automotive applications.
Q: What is the maximum clock frequency supported by the S9KEAZN64AMLC? A: The S9KEAZN64AMLC supports a maximum clock frequency of 48 MHz.
Q: How much flash memory does the S9KEAZN64AMLC have? A: The S9KEAZN64AMLC has 64 KB of flash memory for program storage.
Q: Can I expand the memory capacity of the S9KEAZN64AMLC? A: No, the S9KEAZN64AMLC does not support external memory expansion. However, it does have 4 KB of RAM for data storage.
Q: What communication interfaces are available on the S9KEAZN64AMLC? A: The S9KEAZN64AMLC features several communication interfaces, including UART, SPI, and I2C.
Q: Does the S9KEAZN64AMLC support analog-to-digital conversion (ADC)? A: Yes, the S9KEAZN64AMLC has an integrated 12-bit ADC module for analog signal measurement.
Q: Can I use the S9KEAZN64AMLC for motor control applications? A: Yes, the S9KEAZN64AMLC provides PWM outputs and timers that can be used for motor control applications.
Q: What development tools are available for programming the S9KEAZN64AMLC? A: NXP provides a comprehensive software development kit (SDK) and an integrated development environment (IDE) called MCUXpresso for programming the S9KEAZN64AMLC.
Q: Is the S9KEAZN64AMLC suitable for low-power applications? A: Yes, the S9KEAZN64AMLC features several low-power modes, including stop and standby modes, making it suitable for battery-powered or energy-efficient applications.
Q: Can I use the S9KEAZN64AMLC in safety-critical applications? A: Yes, the S9KEAZN64AMLC is designed to meet certain safety standards, such as ISO 26262, making it suitable for safety-critical applications with appropriate design considerations.