ATTINY417-MFR
Product Overview
Category
The ATTINY417-MFR belongs to the category of microcontrollers.
Use
This microcontroller is commonly used for various embedded applications that require low power consumption and high performance.
Characteristics
- Low power consumption
- High performance
- Small form factor
- Integrated peripherals
- Wide operating voltage range
Package
The ATTINY417-MFR is available in a compact surface mount package.
Essence
The essence of this microcontroller lies in its ability to provide efficient processing capabilities while consuming minimal power.
Packaging/Quantity
The ATTINY417-MFR is typically packaged in reels or trays, with varying quantities depending on the manufacturer's specifications.
Specifications
- Microcontroller Architecture: AVR
- CPU Speed: Up to 20 MHz
- Flash Memory: 4 KB
- RAM: 256 bytes
- EEPROM: 128 bytes
- Operating Voltage Range: 1.8V - 5.5V
- Digital I/O Pins: 14
- Analog Input Pins: 10
- Communication Interfaces: UART, SPI, I2C
- Timers/Counters: 3
- PWM Channels: 6
- ADC Resolution: 10-bit
- Operating Temperature Range: -40°C to +85°C
Detailed Pin Configuration
The ATTINY417-MFR has a total of 24 pins, each serving a specific purpose. The pin configuration is as follows:
- Pin 1: Reset (RESET)
- Pin 2: Digital I/O (PB0)
- Pin 3: Digital I/O (PB1)
- Pin 4: Digital I/O (PB2)
- Pin 5: Digital I/O (PB3)
- Pin 6: Digital I/O (PB4)
- Pin 7: Digital I/O (PB5)
- Pin 8: Digital I/O (PB6)
- Pin 9: Digital I/O (PB7)
- Pin 10: Ground (GND)
- Pin 11: Analog Input (ADC0)
- Pin 12: Analog Input (ADC1)
- Pin 13: Analog Input (ADC2)
- Pin 14: Analog Input (ADC3)
- Pin 15: Analog Input (ADC4)
- Pin 16: Analog Input (ADC5)
- Pin 17: VCC
- Pin 18: Digital I/O (PC0)
- Pin 19: Digital I/O (PC1)
- Pin 20: Digital I/O (PC2)
- Pin 21: Digital I/O (PC3)
- Pin 22: Digital I/O (PC4)
- Pin 23: Digital I/O (PC5)
- Pin 24: Ground (GND)
Functional Features
The ATTINY417-MFR offers a range of functional features, including:
- High-speed processing capabilities
- Low power consumption modes for energy efficiency
- Integrated analog-to-digital converter (ADC) for precise measurements
- Multiple communication interfaces for data exchange
- PWM channels for controlling various devices
- Timers/counters for accurate timing operations
- Flexible digital I/O pins for versatile connectivity
Advantages and Disadvantages
Advantages
- Low power consumption enables longer battery life in portable applications.
- Compact form factor allows for space-efficient designs.
- Wide operating voltage range provides flexibility in different power supply scenarios.
- Integrated peripherals reduce the need for external components, simplifying circuit design.
Disadvantages
- Limited flash memory and RAM may restrict the complexity of applications.
- The number of I/O pins may be insufficient for certain projects requiring extensive connectivity.
Working Principles
The ATTINY417-MFR operates based on the AVR microcontroller architecture. It executes instructions stored in its flash memory, utilizing its CPU to perform various tasks. The microcontroller interacts with external devices through its I/O pins and communication interfaces. It can be programmed using suitable development tools and software.
Detailed Application Field Plans
The ATTINY417-MFR finds applications in various fields, including:
- Internet of Things (IoT) devices
- Home automation systems
- Wearable technology
- Industrial control systems
- Sensor networks
- Consumer electronics
Detailed and Complete Alternative Models
- ATTINY416-MFR
- ATTINY814-MFR
- ATTINY816-MFR
- ATTINY817-MFR
- ATTINY1614-MFR
- ATTINY1616-MFR
- ATTINY1617-MFR
These alternative models offer similar functionalities and characteristics, providing options for different project requirements.
In conclusion, the ATTINY417-MFR is a versatile microcontroller that combines low power consumption with high performance. Its compact size and integrated peripherals make it suitable for a wide range of embedded applications. While it has certain limitations in
技術ソリューションにおける ATTINY417-MFR 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 ATTINY417-MFR in technical solutions:
Q: What is the ATTINY417-MFR microcontroller used for? A: The ATTINY417-MFR is a microcontroller that can be used in various technical solutions, such as IoT devices, home automation systems, robotics, and industrial control applications.
Q: What is the maximum clock frequency supported by the ATTINY417-MFR? A: The ATTINY417-MFR supports a maximum clock frequency of 20 MHz.
Q: How much flash memory does the ATTINY417-MFR have? A: The ATTINY417-MFR has 4 KB of flash memory for storing program code.
Q: Can I use the ATTINY417-MFR for analog sensing applications? A: Yes, the ATTINY417-MFR has a built-in 12-bit ADC (Analog-to-Digital Converter) that can be used for analog sensing applications.
Q: Does the ATTINY417-MFR support communication protocols like I2C and SPI? A: Yes, the ATTINY417-MFR supports both I2C and SPI communication protocols, making it suitable for interfacing with other devices.
Q: What is the power supply voltage range for the ATTINY417-MFR? A: The ATTINY417-MFR can be powered with a voltage range of 1.8V to 5.5V.
Q: Can I use the ATTINY417-MFR in battery-powered applications? A: Yes, the low-power features of the ATTINY417-MFR make it suitable for battery-powered applications, helping to extend battery life.
Q: Does the ATTINY417-MFR have any built-in security features? A: Yes, the ATTINY417-MFR includes a hardware-based cryptographic accelerator for secure communication and data storage.
Q: Can I program the ATTINY417-MFR using the Arduino IDE? A: Yes, the ATTINY417-MFR is supported by the Arduino IDE, making it easy to develop applications using the familiar Arduino programming environment.
Q: What development tools are available for programming the ATTINY417-MFR? A: There are various development tools available, including Atmel Studio, MPLAB X IDE, and Arduino IDE, which can be used to program and debug the ATTINY417-MFR microcontroller.
Please note that these answers are general and may vary depending on specific requirements and use cases.