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DAC1008D750HN/C1:5

DAC1008D750HN/C1:5

Manufacturer No:

DAC1008D750HN/C1:5

Description:

IC DAC 10BIT A-OUT 64HVQFN

Datasheet:

Datasheet

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DAC1008D750HN/C1:5 Specifications

  • Type
    Parameter
  • Mounting Type
    Surface Mount
  • Supplier Device Package
    64-HVQFN (9x9)
  • Package / Case
    64-VFQFN Exposed Pad
  • Operating Temperature
    -40°C ~ 85°C
  • Architecture
    Oversampling Interpolating DAC
  • INL/DNL (LSB)
    -
  • Voltage - Supply, Digital
    1.7V ~ 1.9V
  • Voltage - Supply, Analog
    1.7V ~ 1.9V, 3.13V ~ 3.47V
  • Reference Type
    External, Internal
  • Data Interface
    JESD204A
  • Differential Output
    Yes
  • Output Type
    Current - Unbuffered
  • Settling Time
    20ns (Typ)
  • Number of D/A Converters
    2
  • Number of Bits
    10
  • DigiKey Programmable
    Not Verified
  • Packaging
    Tray
  • Product Status
    Obsolete
  • Series
    -
The LC4512B-75FT256C is a specific type of integrated circuit chip, commonly known as a Field-Programmable Gate Array (FPGA). Here are some advantages and application scenarios of this chip:Advantages: 1. Flexibility: FPGAs are programmable, allowing users to configure the chip's functionality according to their specific requirements. This flexibility makes them suitable for a wide range of applications. 2. High-performance: FPGAs can handle complex logic operations and data processing tasks efficiently, making them ideal for applications that require high-speed and high-performance computing. 3. Parallel processing: FPGAs can perform multiple operations simultaneously, thanks to their parallel processing capabilities. This makes them suitable for applications that require parallel computing, such as image and video processing, cryptography, and data compression. 4. Low power consumption: FPGAs are designed to be power-efficient, consuming less power compared to traditional processors. This makes them suitable for battery-powered devices or applications where power consumption is a concern. 5. Reconfigurability: FPGAs can be reprogrammed multiple times, allowing users to modify or update the chip's functionality without changing the hardware. This feature makes them suitable for applications that require frequent updates or changes in functionality.Application scenarios: 1. Digital signal processing: FPGAs are commonly used in applications that require real-time signal processing, such as audio and video processing, radar systems, telecommunications, and software-defined radios. 2. Embedded systems: FPGAs can be used in embedded systems to implement custom logic and interface with other components. They are often used in industrial automation, robotics, automotive electronics, and aerospace applications. 3. Prototyping and development: FPGAs are widely used in the prototyping and development phase of electronic systems. They allow engineers to quickly test and validate their designs before moving to production. 4. Cryptography and security: FPGAs can be used to implement cryptographic algorithms and secure communication protocols. Their parallel processing capabilities make them suitable for high-speed encryption and decryption tasks. 5. High-performance computing: FPGAs can be used in applications that require high-performance computing, such as data centers, scientific research, and artificial intelligence. They can accelerate specific tasks and offload computation from traditional processors.It's important to note that the specific advantages and application scenarios of the LC4512B-75FT256C chip may vary depending on the requirements and design choices made by the user.
DAC1008D750HN/C1:5 Relevant information