PIC24FJ64GA306-I/PT Microchip PIC24FJ64GA306-I/PT Microcontrollers PIC 8kB 53 I/Os 32MHz

Microchip PIC24FJ64GA306-I/PT Microcontrollers Overview

PIC24FJ64GA306-I/PT; 16bit PIC Microcontroller; 32MHz; 64kb Flash; 64-Pin TQFP

Key Features of Microchip PIC24FJ64GA306-I/PT Microcontrollers

• Designed to max Frequency: 32MHz, helping ensure consistent and reliable operation.
• Built to number of I/Os: 53, making integration easier across a wide range of systems.
• Optimized to core Architecture: PIC, improving robustness in practical applications.
• Optimized to rAM Size: 8kB, improving robustness in practical applications.

Microchip PIC24FJ64GA306-I/PT Microcontrollers Applications

Automotive Applications

• Well-suited for tire pressure monitoring systems reading pressure/temperature and transmitting telemetry, helping designers meet typical integration requirements.
• Often used in anti-lock braking systems monitoring wheel speed and modulating brake pressure rapidly, where predictable behavior and reliability are important.
• Well-suited for headlight controllers managing auto high-beam, leveling motors, and DRL patterns, helping designers meet typical integration requirements.
• Often used in lane departure systems processing camera data and triggering haptic/visual warnings, where predictable behavior and reliability are important.
• Often used in engine control units managing fuel injection, ignition timing, and sensor fusion logic, where predictable behavior and reliability are important.

Internet of Things (IoT)

• Well-suited for cold-chain trackers logging temperature/shock events for logistics compliance, helping designers meet typical integration requirements.
• Often used in connected irrigation controllers controlling valves based on schedules and sensor feedback, where predictable behavior and reliability are important.
• Commonly applied in environmental monitoring nodes measuring air quality (PM/VOC/CO?) and logging trends, supporting stable and efficient system performance.
• Commonly applied in smart streetlights adjusting brightness based on ambient light and motion triggers, supporting stable and efficient system performance.
• Commonly applied in smart trash bins detecting fill levels and sending pickup optimization signals, supporting stable and efficient system performance.

Entertainment and Media

• Often used in stage pyrotechnic safety controllers enforcing arming logic and interlock checks, where predictable behavior and reliability are important.
• Well-suited for wireless microphone receivers managing channel selection and RF status indicators, helping designers meet typical integration requirements.
• Well-suited for projection mapping controllers coordinating triggers and syncing to sound/light cues, helping designers meet typical integration requirements.
• Often used in stage lighting controllers managing effects, dimmer curves, and show timing cues, where predictable behavior and reliability are important.
• Often used in theme park ride controllers managing safety sensors, sequencing, and emergency stops, where predictable behavior and reliability are important.

Transportation

• Often used in airport baggage handling controllers routing bags using sensors and diverter actuators, where predictable behavior and reliability are important.
• Often used in escalator control systems monitoring speed, load, and emergency stop circuits, where predictable behavior and reliability are important.
• Commonly applied in train onboard control units supervising doors, braking, and diagnostics telemetry, supporting stable and efficient system performance.
• Well-suited for automated fare machines reading cards and managing ticket printing mechanisms, helping designers meet typical integration requirements.
• Often used in railway signaling systems controlling track signals and enforcing safe block occupancy, where predictable behavior and reliability are important.

Wearable Devices

• Commonly applied in health monitoring wearables tracking vital signs and syncing data to mobile apps, supporting stable and efficient system performance.
• Often used in vR controllers tracking motion and buttons with low-latency sensor fusion, where predictable behavior and reliability are important.
• Often used in smart helmets monitoring impacts and logging safety events for review, where predictable behavior and reliability are important.
• Well-suited for haptic wearables generating vibration cues for navigation or accessibility prompts, helping designers meet typical integration requirements.
• Commonly applied in smartwatches managing displays, sensors, notifications, and battery optimization, supporting stable and efficient system performance.