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P1014NXE5HHB
Manufacturer No:
P1014NXE5HHB
Manufacturer:
Description:
IC MPU QORIQ P1 800MHZ 425TEPBGA
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P1014NXE5HHB Specifications
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TypeParameter
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Supplier Device Package425-TEPBGA I (19x19)
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Package / Case425-FBGA
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Mounting TypeSurface Mount
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Security FeaturesBoot Security, Cryptography, Random Number Generator, Secure Fusebox
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Operating Temperature-40°C ~ 105°C (TA)
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Voltage - I/O-
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USBUSB 2.0 + PHY (1)
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SATASATA 3Gbps (2)
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Ethernet10/100/1000Mbps (2)
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Display & Interface Controllers-
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Graphics AccelerationNo
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RAM ControllersDDR3, DDR3L
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Co-Processors/DSPSecurity; SEC 4.4
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Speed800MHz
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Number of Cores/Bus Width1 Core, 32-Bit
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Core ProcessorPowerPC e500v2
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PackagingTray
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Product StatusObsolete
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SeriesQorIQ P1
The 5ASXFB5G4F35C4N is an integrated circuit chip from Intel's Stratix V family of field-programmable gate arrays (FPGAs). Here are some advantages and application scenarios of this chip:Advantages: 1. High Performance: The 5ASXFB5G4F35C4N chip offers high-speed processing capabilities, making it suitable for applications that require complex computations and real-time data processing. 2. Flexibility: Being an FPGA, it allows for reprogramming and customization of the chip's functionality even after deployment, enabling adaptability to changing requirements. 3. Parallel Processing: FPGAs excel at parallel processing tasks, allowing for efficient execution of multiple tasks simultaneously. 4. Low Power Consumption: The chip is designed to be power-efficient, making it suitable for applications where energy consumption is a concern. 5. High Integration: The 5ASXFB5G4F35C4N chip integrates various components like logic elements, memory blocks, and high-speed transceivers, reducing the need for external components and simplifying the overall system design.Application Scenarios: 1. Communications: The high-speed transceivers and parallel processing capabilities of the chip make it suitable for applications like wireless communication systems, network routers, and data centers. 2. Signal Processing: The chip's ability to process large amounts of data in real-time makes it ideal for applications like digital signal processing, image and video processing, and software-defined radio. 3. Industrial Automation: The flexibility and high performance of the chip make it suitable for industrial automation applications like robotics, machine vision, and control systems. 4. Aerospace and Defense: The chip's high-speed processing and low power consumption make it suitable for aerospace and defense applications like radar systems, avionics, and secure communication systems. 5. High-Performance Computing: The chip's parallel processing capabilities and high integration make it suitable for applications in the field of high-performance computing, such as scientific simulations, financial modeling, and data analytics.It's important to note that the specific advantages and application scenarios may vary depending on the requirements and design choices made by the system designer.
