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MC9S12C64VFUE
Product Overview
Category
MC9S12C64VFUE belongs to the category of microcontrollers.
Use
It is primarily used for embedded systems and applications that require control and processing capabilities.
Characteristics
- 16-bit microcontroller
- High-performance CPU
- Integrated peripherals
- Low power consumption
- Enhanced security features
Package
MC9S12C64VFUE is available in a compact package, suitable for surface mount technology (SMT) assembly.
Essence
The essence of MC9S12C64VFUE lies in its ability to provide efficient control and processing capabilities within a small form factor.
Packaging/Quantity
MC9S12C64VFUE is typically packaged in reels or trays, with a standard quantity of 250 units per reel/tray.
Specifications
- Architecture: 16-bit
- Flash Memory: 64KB
- RAM: 4KB
- Operating Voltage: 2.35V to 5.5V
- Clock Speed: Up to 25MHz
- Number of I/O Pins: 52
- Communication Interfaces: UART, SPI, I2C
- Analog-to-Digital Converter (ADC): 10-bit, 8 channels
- Timers/Counters: 8-bit and 16-bit timers/counters
Detailed Pin Configuration
The pin configuration of MC9S12C64VFUE is as follows:
- VDD - Power supply voltage
- VSS - Ground
- RESET - Reset signal input
- IRQ - Interrupt request input
- PT0 - Port T0
- PT1 - Port T1
- PT2 - Port T2
- PT3 - Port T3
- PT4 - Port T4
- PT5 - Port T5
- PT6 - Port T6
- PT7 - Port T7
- PTH0 - Port H0
- PTH1 - Port H1
- PTH2 - Port H2
- PTH3 - Port H3
- PTH4 - Port H4
- PTH5 - Port H5
- PTH6 - Port H6
- PTH7 - Port H7
- PTJ0 - Port J0
- PTJ1 - Port J1
- PTJ2 - Port J2
- PTJ3 - Port J3
- PTJ4 - Port J4
- PTJ5 - Port J5
- PTJ6 - Port J6
- PTJ7 - Port J7
- XTAL - Crystal oscillator input
- EXTAL - Crystal oscillator output
- VDDA - Analog power supply voltage
- VSSA - Analog ground
- AD0 - Analog input 0
- AD1 - Analog input 1
- AD2 - Analog input 2
- AD3 - Analog input 3
- AD4 - Analog input 4
- AD5 - Analog input 5
- AD6 - Analog input 6
- AD7 - Analog input 7
- ADCONV - Analog-to-digital converter control signal
- SS - Slave select for SPI communication
- SCK - Serial clock for SPI communication
- MOSI - Master output, slave input for SPI communication
- MISO - Master input, slave output for SPI communication
- SDA - Serial data line for I2C communication
- SCL - Serial clock line for I2C communication
- TXD - Transmit data for UART communication
- RXD - Receive data for UART communication
- T0 - Timer/Counter 0 input
- T1 - Timer/Counter 1 input
- T2 - Timer/Counter 2 input
Functional Features
- High-performance CPU with efficient instruction set
- Integrated peripherals for enhanced functionality
- Low power consumption for energy-efficient operation
- Enhanced security features to protect sensitive data
- Flexible communication interfaces for seamless connectivity
- Analog-to-digital converter for precise analog signal processing
- Timers/counters for accurate timing and event counting
Advantages and Disadvantages
Advantages
- Compact size and low power consumption make it suitable for embedded systems
- High-performance CPU enables efficient control and processing
- Integrated peripherals provide enhanced functionality
- Enhanced security features ensure data protection
Disadvantages
- Limited memory capacity compared to some other microcontrollers
- May require additional external components for certain applications
Working Principles
MC9S12C64VFUE operates based on the principles of
Enumere 10 preguntas y respuestas comunes relacionadas con la aplicación de MC9S12C64VFUE en soluciones técnicas
Sure! Here are 10 common questions and answers related to the application of MC9S12C64VFUE in technical solutions:
Q: What is MC9S12C64VFUE? A: MC9S12C64VFUE is a microcontroller from the MC9S12 family, specifically designed for embedded applications.
Q: What are the key features of MC9S12C64VFUE? A: Some key features include a 16-bit CPU core, 64KB flash memory, 2KB RAM, multiple communication interfaces, and analog-to-digital converters.
Q: What kind of technical solutions can MC9S12C64VFUE be used for? A: MC9S12C64VFUE can be used in various technical solutions such as automotive systems, industrial control, consumer electronics, and more.
Q: How does MC9S12C64VFUE handle communication interfaces? A: MC9S12C64VFUE supports multiple communication interfaces like UART, SPI, I2C, CAN, and LIN, making it suitable for connecting with other devices.
Q: Can MC9S12C64VFUE be programmed using C/C++? A: Yes, MC9S12C64VFUE can be programmed using C/C++ programming languages, along with assembly language if needed.
Q: What development tools are available for MC9S12C64VFUE? A: There are several development tools available, including integrated development environments (IDEs), compilers, debuggers, and programmers.
Q: Is MC9S12C64VFUE suitable for real-time applications? A: Yes, MC9S12C64VFUE is suitable for real-time applications due to its fast processing speed and support for interrupt handling.
Q: Can MC9S12C64VFUE be used in low-power applications? A: Yes, MC9S12C64VFUE offers various power-saving modes and features that make it suitable for low-power applications.
Q: Are there any development boards available for MC9S12C64VFUE? A: Yes, there are development boards specifically designed for MC9S12C64VFUE, which provide a convenient platform for prototyping and testing.
Q: Where can I find documentation and resources for MC9S12C64VFUE? A: You can find documentation, datasheets, application notes, and other resources on the manufacturer's website or through online communities and forums dedicated to MC9S12 microcontrollers.
Please note that the answers provided here are general and may vary depending on specific requirements and use cases.