ATTINY416-MNR

Product Overview

• Category: Microcontroller
• Use: Embedded systems, Internet of Things (IoT) devices, and other electronic applications
• Characteristics:
  • Low power consumption
  • High performance
  • Small form factor
  • Wide range of peripherals
• Package: QFN (Quad Flat No-leads)
• Essence: A versatile microcontroller designed for various applications requiring low power and high performance.
• Packaging/Quantity: Available in reels with a quantity of 2500 units per reel.

Specifications

• Architecture: AVR
• Flash Memory: 16KB
• SRAM: 2KB
• EEPROM: 256B
• Operating Voltage: 1.8V to 5.5V
• Maximum CPU Speed: 20MHz
• Digital I/O Pins: 14
• Analog Input Pins: 10
• Communication Interfaces: UART, SPI, I2C
• Timers/Counters: 4
• PWM Channels: 6
• ADC Resolution: 10-bit
• Temperature Range: -40°C to +105°C

Pin Configuration

The ATTINY416-MNR microcontroller has a total of 24 pins. The pin configuration is as follows:

```

---

| | --|VCC GND|-- --|PB3 PA0|-- --|PB2 PA1|-- --|PB1 PA2|-- --|PB0 PA3|-- --|RESET PD0|-- --|PA7 PC0|-- --|PA6 PC1|-- --|PA5 PC2|-- --|PA4 PC3|-- --|PC4 PC5|-- |_______| ```

Functional Features

• Low power consumption allows for extended battery life in portable devices.
• High-performance AVR architecture enables efficient execution of complex tasks.
• Wide range of peripherals, including UART, SPI, and I2C interfaces, provide flexibility for various applications.
• Multiple timers/counters and PWM channels allow precise timing and control.
• 10-bit ADC provides accurate analog-to-digital conversion.

Advantages and Disadvantages

Advantages

• Low power consumption extends battery life.
• Versatile microcontroller suitable for a wide range of applications.
• Compact form factor saves space in electronic designs.
• High-performance architecture ensures efficient execution of tasks.
• Wide range of peripherals allows for flexible connectivity options.

Disadvantages

• Limited flash memory and SRAM compared to higher-end microcontrollers.
• Less suitable for applications requiring extensive computational power.

Working Principles

The ATTINY416-MNR operates based on the AVR architecture. It executes instructions stored in its flash memory, interacting with various peripherals and input/output pins to perform desired tasks. The microcontroller can be programmed using popular development tools and programming languages, allowing developers to create custom firmware to meet specific application requirements.

Detailed Application Field Plans

The ATTINY416-MNR is well-suited for various applications, including but not limited to:

1. Internet of Things (IoT) devices: The low power consumption and small form factor make it ideal for IoT applications where energy efficiency and compact size are crucial.
2. Home automation systems: With its wide range of peripherals and communication interfaces, the microcontroller can be used to control and monitor various home automation devices.
3. Sensor networks: The ATTINY416-MNR can interface with multiple sensors, making it suitable for building sensor networks for environmental monitoring or industrial applications.
4. Wearable devices: Its small size and low power consumption make it suitable for wearable electronics such as fitness trackers, smartwatches, and health monitoring devices.

Detailed and Complete Alternative Models

• ATTINY412-MNR: Similar to ATTINY416-MNR but with 8KB flash memory instead of 16KB.
• ATTINY814-MNR: A more advanced version with additional features such as a higher number of I/O pins and more memory options.
• ATTINY1617-MNR: Offers enhanced performance and increased memory capacity compared to ATTINY416-MNR.

These alternative models provide developers with options based on their specific requirements, allowing them to choose the most suitable microcontroller for their projects.

In conclusion, the ATTINY416-MNR is a versatile microcontroller that combines low power consumption, high performance, and a wide range of peripherals. Its compact size and extensive application field plans make it an excellent choice for various electronic applications, particularly in the IoT domain. Developers can take advantage of its functional features and consider alternative models to meet their specific project needs.