DSPIC30F4011-20E/PT Microchip DSPIC30F4011-20E/PT Microcontrollers dsPIC 2kB 30 I/Os 20MHz

Microchip DSPIC30F4011-20E/PT Microcontrollers Overview

dsPIC series Microcontroller IC 16-Bit 2 MIPS 48KB (16K x 24) FLASH 44-TQFP (1×1)

Key Features of Microchip DSPIC30F4011-20E/PT Microcontrollers

• Engineered to core Architecture: dsPIC, supporting dependable performance in real-world designs.
• Designed to max Frequency: 20MHz, helping ensure consistent and reliable operation.
• Optimized to number of I/Os: 30, improving robustness in practical applications.
• Engineered to rAM Size: 2kB, supporting dependable performance in real-world designs.

Microchip DSPIC30F4011-20E/PT Microcontrollers Applications

Experimental and Future Uses

• Commonly applied in nanotechnology fabrication controllers coordinating micro-positioners and sensor feedback, supporting stable and efficient system performance.
• Commonly applied in smart materials experiments controlling heating/strain to observe phase changes, supporting stable and efficient system performance.
• Well-suited for smart prosthetics controlling actuators using sensor fusion and intent estimation, helping designers meet typical integration requirements.
• Commonly applied in autonomous research buoys monitoring oceans and transmitting summarized sensor data, supporting stable and efficient system performance.
• Well-suited for space robotics subsystems managing joint control and radiation-tolerant watchdog logic, helping designers meet typical integration requirements.

Energy and Power Systems

• Commonly applied in power grid monitoring devices detecting faults and reporting status telemetry, supporting stable and efficient system performance.
• Often used in battery management systems monitoring voltage/temperature and balancing battery cells, where predictable behavior and reliability are important.
• Well-suited for energy storage controllers coordinating charge/discharge schedules and thermal control, helping designers meet typical integration requirements.
• Commonly applied in backup generator controllers sequencing start/stop and monitoring oil/temp parameters, supporting stable and efficient system performance.
• Well-suited for load shedding controllers disconnecting noncritical loads during peak demand events, helping designers meet typical integration requirements.

Education and Research

• Well-suited for student-built weather stations collecting data and visualizing results in class, helping designers meet typical integration requirements.
• Commonly applied in robotics competition timers controlling scoring sensors and match sequence logic, supporting stable and efficient system performance.
• Often used in scientific sensors measuring physical phenomena and applying calibration compensation, where predictable behavior and reliability are important.
• Commonly applied in research prototypes testing new control algorithms on real hardware platforms, supporting stable and efficient system performance.
• Commonly applied in automated test benches controlling measurements, relays, and repeatable sequences, supporting stable and efficient system performance.

Internet of Things (IoT)

• Well-suited for smart home hubs acting as IoT coordinators for device discovery and automation, helping designers meet typical integration requirements.
• Often used in smart greenhouse nodes controlling fans/heaters and logging climate conditions, where predictable behavior and reliability are important.
• Often used in smart farming drones coordinating navigation, sensors, and telemetry reporting, where predictable behavior and reliability are important.
• Commonly applied in smart retail shelf sensors monitoring inventory levels and generating restock alerts, supporting stable and efficient system performance.
• Often used in smart trash bins detecting fill levels and sending pickup optimization signals, where predictable behavior and reliability are important.

Aerospace and Defense

• Well-suited for space probes managing power budgeting, instrument control, and communication schedules, helping designers meet typical integration requirements.
• Commonly applied in electronic warfare controllers managing waveform timing and subsystem coordination, supporting stable and efficient system performance.
• Commonly applied in aircraft health monitors logging vibration/temperature and reporting maintenance events, supporting stable and efficient system performance.
• Often used in satellite subsystems handling telemetry, command reception, and subsystem coordination, where predictable behavior and reliability are important.
• Commonly applied in avionics displays managing flight information, warnings, and pilot interaction inputs, supporting stable and efficient system performance.