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DSPIC33FJ256MC710-I/PF
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DSPIC33FJ256MC710-I/PF

Overview

Category: Microcontroller
Use: Embedded Systems
Characteristics: High-performance, low-power consumption
Package: 64-pin TQFP
Essence: Digital Signal Controller
Packaging/Quantity: Tray / 160 units per tray

Specifications

  • Architecture: Modified Harvard
  • CPU Speed: 40 MIPS
  • Flash Memory: 256 KB
  • RAM: 30 KB
  • Operating Voltage Range: 2.5V to 3.6V
  • Operating Temperature Range: -40°C to +85°C
  • Number of I/O Pins: 53
  • Analog-to-Digital Converter (ADC): 10-bit, 16 channels
  • Digital-to-Analog Converter (DAC): 12-bit, 4 channels
  • Communication Interfaces: UART, SPI, I2C, CAN
  • Timers: 5 x 16-bit, 1 x 32-bit
  • PWM Channels: 9
  • External Oscillator Frequency Range: 4 MHz to 40 MHz

Pin Configuration

The DSPIC33FJ256MC710-I/PF microcontroller has a total of 64 pins. The pin configuration is as follows:

  1. VDD
  2. VSS
  3. AN0/RB0
  4. AN1/RB1
  5. AN2/RB2
  6. AN3/RB3
  7. AN4/RB4
  8. AN5/RB5
  9. AN6/RB6
  10. AN7/RB7
  11. AN8/RB8
  12. AN9/RB9
  13. AN10/RB10
  14. AN11/RB11
  15. AN12/RB12
  16. AN13/RB13
  17. AN14/RB14
  18. AN15/RB15
  19. VCAP
  20. VSS
  21. AVDD
  22. AVSS
  23. OSC1/CLKI
  24. OSC2/CLKO
  25. PGD1/RP0
  26. PGC1/RP1
  27. PGD2/RP2
  28. PGC2/RP3
  29. RP4
  30. RP5
  31. RP6
  32. RP7
  33. RP8
  34. RP9
  35. RP10
  36. RP11
  37. RP12
  38. RP13
  39. RP14
  40. RP15
  41. RP16
  42. RP17
  43. RP18
  44. RP19
  45. RP20
  46. RP21
  47. RP22
  48. RP23
  49. RP24
  50. RP25
  51. RP26
  52. RP27
  53. RP28
  54. RP29
  55. RP30
  56. RP31
  57. RP32
  58. RP33
  59. RP34
  60. RP35
  61. RP36
  62. RP37
  63. RP38
  64. RP39

Functional Features

  • High-performance digital signal processing capabilities
  • Low-power consumption for energy-efficient applications
  • Enhanced connectivity options with UART, SPI, I2C, and CAN interfaces
  • Ample memory capacity for storing program code and data
  • Multiple timers and PWM channels for precise timing and control
  • Analog-to-digital and digital-to-analog converters for interfacing with analog sensors and actuators
  • Robust operating voltage and temperature range for versatile applications

Advantages and Disadvantages

Advantages: - High-performance processing capabilities - Low-power consumption for energy efficiency - Versatile communication interfaces - Ample memory capacity - Precise timing and control features - Analog interfacing capabilities - Wide operating voltage and temperature range

Disadvantages: - Limited number of I/O pins compared to some other microcontrollers - Higher cost compared to lower-end microcontrollers

Working Principles

The DSPIC33FJ256MC710-I/PF is based on a modified Harvard architecture, combining the benefits of both Harvard and Von Neumann architectures. It utilizes a high-performance CPU that can execute instructions at a speed of 40 MIPS. The microcontroller operates at a low voltage range of 2.5V to 3.6V, making it suitable for battery-powered applications.

The microcontroller incorporates various peripherals and interfaces, such as UART, SPI, I2C, and CAN, enabling seamless communication with external devices. It also features multiple timers and PWM channels for precise timing and control of connected devices.

The analog-to-digital and digital-to-analog converters allow the micro

Noem 10 veelgestelde vragen en antwoorden met betrekking tot de toepassing van DSPIC33FJ256MC710-I/PF in technische oplossingen

  1. What is the maximum operating frequency of DSPIC33FJ256MC710-I/PF?

    • The maximum operating frequency of DSPIC33FJ256MC710-I/PF is 40 MHz.

  2. What are the key features of DSPIC33FJ256MC710-I/PF?

    • DSPIC33FJ256MC710-I/PF features high performance, integrated peripherals, and a wide operating voltage range.

  3. Can DSPIC33FJ256MC710-I/PF be used for motor control applications?

    • Yes, DSPIC33FJ256MC710-I/PF is suitable for motor control applications due to its advanced PWM modules and motor control peripherals.

  4. What communication interfaces are supported by DSPIC33FJ256MC710-I/PF?

    • DSPIC33FJ256MC710-I/PF supports various communication interfaces including SPI, I2C, UART, and CAN.

  5. Is DSPIC33FJ256MC710-I/PF suitable for power supply applications?

    • Yes, DSPIC33FJ256MC710-I/PF is well-suited for power supply applications with its integrated analog-to-digital converters and high-speed PWM modules.

  6. What development tools are available for programming DSPIC33FJ256MC710-I/PF?

    • Development tools such as MPLAB X IDE and MPLAB XC compilers can be used for programming DSPIC33FJ256MC710-I/PF.

  7. Does DSPIC33FJ256MC710-I/PF support real-time control applications?

    • Yes, DSPIC33FJ256MC710-I/PF is designed to handle real-time control applications with its high-performance core and peripherals.

  8. What are the recommended operating conditions for DSPIC33FJ256MC710-I/PF?

    • The recommended operating voltage range for DSPIC33FJ256MC710-I/PF is 2.5V to 5.5V, and the temperature range is -40°C to 125°C.

  9. Can DSPIC33FJ256MC710-I/PF be used in automotive applications?

    • Yes, DSPIC33FJ256MC710-I/PF is suitable for automotive applications due to its robust design and wide operating temperature range.

  10. Are there any application notes or reference designs available for DSPIC33FJ256MC710-I/PF?

    • Yes, Microchip provides application notes and reference designs to assist in implementing DSPIC33FJ256MC710-I/PF in various technical solutions.