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MAX399ESE+

MAX399ESE+

Manufacturer No:

MAX399ESE+

Description:

IC SWITCH SP4T X 2 100OHM 16SOIC

Datasheet:

Datasheet

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MAX399ESE+ Specifications

  • Type
    Parameter
  • Supplier Device Package
    16-SOIC
  • Package / Case
    16-SOIC (0.154", 3.90mm Width)
  • Mounting Type
    Surface Mount
  • Operating Temperature
    -40°C ~ 85°C (TA)
  • Crosstalk
    -92dB @ 100kHz
  • Current - Leakage (IS(off)) (Max)
    100pA
  • Channel Capacitance (CS(off), CD(off))
    11pF, 20pF
  • Charge Injection
    2pC
  • -3db Bandwidth
    -
  • Switch Time (Ton, Toff) (Max)
    150ns, 150ns
  • Voltage - Supply, Dual (V±)
    ±3V ~ 8V
  • Voltage - Supply, Single (V+)
    3V ~ 15V
  • Channel-to-Channel Matching (ΔRon)
    6Ohm (Max)
  • On-State Resistance (Max)
    100Ohm
  • Number of Circuits
    2
  • Multiplexer/Demultiplexer Circuit
    4:1
  • Switch Circuit
    SP4T
  • Packaging
    Tube
  • Product Status
    Active
  • Series
    -
The XC95144XV-5TQG100C is a specific type of integrated circuit chip, known as a Field-Programmable Gate Array (FPGA). Here are some advantages and application scenarios of this chip:Advantages: 1. Flexibility: FPGAs can be reprogrammed or reconfigured to perform different functions, making them highly flexible compared to fixed-function integrated circuits. 2. High-performance: FPGAs can achieve high processing speeds and low latency, making them suitable for applications that require real-time processing or high-speed data handling. 3. Parallel processing: FPGAs can perform multiple tasks simultaneously, thanks to their parallel processing capabilities. This makes them ideal for applications that require parallel computing, such as image and signal processing. 4. Customization: FPGAs allow designers to create custom logic circuits tailored to their specific requirements, enabling the development of highly optimized and efficient systems. 5. Prototyping and testing: FPGAs are commonly used for prototyping and testing electronic systems before manufacturing custom Application-Specific Integrated Circuits (ASICs). They provide a cost-effective way to validate designs and make iterative improvements.Application scenarios: 1. Digital signal processing: FPGAs are widely used in applications such as audio and video processing, telecommunications, and radar systems, where real-time processing of large amounts of data is required. 2. Embedded systems: FPGAs can be used in embedded systems to implement custom logic and interface with other components, enabling the development of highly integrated and efficient systems. 3. Robotics and automation: FPGAs are used in robotics and automation systems for tasks such as motor control, sensor interfacing, and real-time decision-making. 4. Aerospace and defense: FPGAs are employed in aerospace and defense applications, including avionics, radar systems, and secure communications, due to their high performance, reliability, and reconfigurability. 5. Cryptography and security: FPGAs can be used to implement cryptographic algorithms and secure communication protocols, providing hardware-level security solutions. 6. Data centers and networking: FPGAs are increasingly being used in data centers and networking equipment to accelerate data processing, improve network performance, and enable software-defined networking.These are just a few examples of the advantages and application scenarios of the XC95144XV-5TQG100C FPGA chip. The specific usage will depend on the requirements and design goals of the system being developed.
MAX399ESE+ Relevant information