TMSC6727BZDH350TAN

Product Overview

• Category: Integrated Circuit (IC)
• Use: Signal Processing
• Characteristics: High-performance, low-power consumption
• Package: BGA (Ball Grid Array)
• Essence: Digital Signal Processor (DSP)
• Packaging/Quantity: Tray packaging, quantity varies

Specifications

• Manufacturer: Texas Instruments
• Model Number: TMSC6727BZDH350TAN
• Architecture: TMS320C67x
• Clock Frequency: 350 MHz
• Data Bus Width: 32-bit
• Program Memory Size: 256 KB
• RAM Size: 544 KB
• Operating Voltage: 1.2V - 1.4V
• Operating Temperature: -40°C to +85°C
• Package Dimensions: 19mm x 19mm

Detailed Pin Configuration

The TMSC6727BZDH350TAN has a total of 176 pins. The pin configuration is as follows:

• Pins 1-8: Power Supply and Ground Pins
• Pins 9-16: External Memory Interface Pins
• Pins 17-24: Serial Port Pins
• Pins 25-32: General-Purpose Input/Output (GPIO) Pins
• Pins 33-40: Timer Pins
• Pins 41-48: Interrupt Pins
• Pins 49-56: Clock Pins
• Pins 57-64: Address/Data Bus Pins
• Pins 65-72: Control Pins
• Pins 73-80: JTAG Interface Pins
• Pins 81-88: Debug Interface Pins
• Pins 89-96: Reserved Pins
• Pins 97-104: Analog-to-Digital Converter (ADC) Pins
• Pins 105-112: Digital-to-Analog Converter (DAC) Pins
• Pins 113-120: Serial Peripheral Interface (SPI) Pins
• Pins 121-128: Inter-Integrated Circuit (I2C) Pins
• Pins 129-136: Universal Asynchronous Receiver/Transmitter (UART) Pins
• Pins 137-144: Reserved Pins
• Pins 145-152: External Memory Interface Pins
• Pins 153-160: Reserved Pins
• Pins 161-168: Reserved Pins
• Pins 169-176: Reserved Pins

Functional Features

• High-performance digital signal processing capabilities
• Low-power consumption for energy-efficient operation
• Integrated peripherals for versatile applications
• Advanced memory management for efficient data handling
• Real-time control and processing capabilities
• Support for various communication protocols
• Flexible and programmable architecture for customization

Advantages and Disadvantages

Advantages

• High processing power for demanding signal processing tasks
• Low power consumption extends battery life in portable devices
• Versatile peripheral integration reduces external component count
• Efficient memory management enhances overall system performance
• Real-time capabilities enable time-critical applications
• Programmability allows customization for specific requirements

Disadvantages

• Complex programming and development process
• Steep learning curve for beginners
• Limited availability of alternative models with similar features
• Relatively high cost compared to simpler microcontrollers

Working Principles

The TMSC6727BZDH350TAN is based on the TMS320C67x architecture, which is specifically designed for digital signal processing applications. It utilizes a combination of hardware and software to perform complex mathematical calculations and manipulate digital signals in real-time.

The processor's core consists of multiple execution units, including arithmetic logic units (ALUs), multiply-accumulate units (MACs), and control units. These units work together to execute instructions and perform various signal processing operations.

The TMSC6727BZDH350TAN also features integrated peripherals such as timers, serial ports, GPIO pins, ADCs, DACs, SPI, I2C, and UART interfaces. These peripherals enable seamless communication with external devices and facilitate data acquisition and control functions.

Detailed Application Field Plans

The TMSC6727BZDH350TAN is widely used in various application fields, including:

1. Audio Processing: The DSP's high-performance capabilities make it suitable for audio signal processing applications such as audio effects, noise cancellation, and audio synthesis.
2. Telecommunications: The processor's real-time processing and communication interfaces make it ideal for telecommunication systems, including voice and data transmission, wireless communication, and network infrastructure.
3. Industrial Automation: The DSP's ability to handle complex algorithms and control tasks makes it valuable in industrial automation applications, such as motor control, robotics, and process control.
4. Medical Devices: The processor's low-power consumption and signal processing capabilities are utilized in medical devices like patient monitoring systems, medical imaging, and diagnostic equipment.
5. Automotive