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MAX326CSE+

MAX326CSE+

Manufacturer No:

MAX326CSE+

Description:

IC SW SPST-NCX4 3.5KOHM 16SOIC

Datasheet:

Datasheet

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MAX326CSE+ Specifications

  • Type
    Parameter
  • Supplier Device Package
    16-SOIC
  • Package / Case
    16-SOIC (0.154", 3.90mm Width)
  • Mounting Type
    Surface Mount
  • Operating Temperature
    0°C ~ 70°C (TA)
  • Crosstalk
    -90dB @ 100kHz
  • Current - Leakage (IS(off)) (Max)
    10pA
  • Channel Capacitance (CS(off), CD(off))
    1.7pF, 1.7pF
  • Charge Injection
    2pC
  • -3db Bandwidth
    -
  • Switch Time (Ton, Toff) (Max)
    1µs, 500ns
  • Voltage - Supply, Dual (V±)
    ±5V ~ 18V
  • Voltage - Supply, Single (V+)
    10V ~ 30V
  • Channel-to-Channel Matching (ΔRon)
    175Ohm
  • On-State Resistance (Max)
    3.5kOhm
  • Number of Circuits
    4
  • Multiplexer/Demultiplexer Circuit
    1:1
  • Switch Circuit
    SPST - NC
  • Packaging
    Tube
  • Product Status
    Active
  • Series
    -
The M2S150-FCVG484 integrated circuit chip, also known as a field-programmable gate array (FPGA), offers several advantages and can be applied in various scenarios. Here are some of the advantages and application scenarios of the M2S150-FCVG484:Advantages: 1. Flexibility: FPGAs are programmable devices, 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 provide high-speed processing capabilities, making them suitable for applications that require real-time data processing or high-performance computing. 3. Parallel processing: FPGAs can perform multiple tasks simultaneously, leveraging parallel processing capabilities. This makes them suitable for applications that require parallel computing, such as image and video processing, cryptography, and machine learning. 4. Low power consumption: FPGAs can be power-efficient compared to other programmable devices or general-purpose processors. This advantage makes them suitable for applications where power consumption is a concern, such as portable devices or battery-powered systems. 5. Reconfigurability: FPGAs can be reprogrammed multiple times, allowing for updates or changes in functionality without requiring hardware modifications. This advantage makes them suitable for applications that require frequent updates or customization.Application Scenarios: 1. Digital signal processing (DSP): FPGAs can be used for real-time signal processing applications, such as audio and video processing, radar systems, software-defined radios, and telecommunications. 2. Embedded systems: FPGAs can be integrated into embedded systems to provide hardware acceleration, interface with other components, or implement custom logic. This makes them suitable for applications like robotics, industrial automation, automotive electronics, and IoT devices. 3. Prototyping and emulation: FPGAs can be used for rapid prototyping and emulation of digital systems. They allow designers to test and validate their designs before manufacturing custom ASICs (Application-Specific Integrated Circuits). 4. High-performance computing: FPGAs can be used in high-performance computing applications, such as data centers, scientific simulations, and financial modeling, to accelerate specific algorithms or tasks. 5. Aerospace and defense: FPGAs are commonly used in aerospace and defense applications due to their high-performance, reconfigurability, and ability to withstand harsh environments. They can be used in radar systems, avionics, communication systems, and cryptography.These are just a few examples of the advantages and application scenarios of the M2S150-FCVG484 FPGA chip. The specific use cases may vary depending on the requirements and needs of the application.
MAX326CSE+ Relevant information