Allicdata Part #: | XCV400E-7BG432I-ND |
Manufacturer Part#: |
XCV400E-7BG432I |
Price: | $ 0.00 |
Product Category: | Integrated Circuits (ICs) |
Manufacturer: | Xilinx Inc. |
Short Description: | IC FPGA 316 I/O 432MBGA |
More Detail: | N/A |
DataSheet: | XCV400E-7BG432I Datasheet/PDF |
Quantity: | 1000 |
Series: | Virtex®-E |
Part Status: | Obsolete |
Number of LABs/CLBs: | 2400 |
Number of Logic Elements/Cells: | 10800 |
Total RAM Bits: | 163840 |
Number of I/O: | 316 |
Number of Gates: | 569952 |
Voltage - Supply: | 1.71 V ~ 1.89 V |
Mounting Type: | Surface Mount |
Operating Temperature: | -40°C ~ 100°C (TJ) |
Package / Case: | 432-LBGA Exposed Pad, Metal |
Supplier Device Package: | 432-MBGA (40x40) |
Base Part Number: | XCV400E |
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Embedded - FPGAs (Field Programmable Gate Array)
A field programmable gate array (FPGA) is an integrated circuit (IC) intended to be customized after manufacture. It\'s composed of large numbers of small circuit blocks that can be interconnected by the customer to implement specific logical functions. Epic FPGAs like XCV400E-7BG432I have the capacity to handle a wider range of operating parameters than most other embedded FPGAs, making them ideal for various applications.
XCV400E-7BG432I Application Field
FPGAs like XCV400E-7BG432I are primarily used in embedded applications, such as in robotics, medical instruments, and advanced automation systems. These FPGAs generally have limited onboard memory and I/O interfaces, and are used for tasks that require a relatively low-cost computing solution. In addition, they are also used for prototyping applications and DSP compute intensive applications.
In robotics, XCV400E-7BG432I can be used to design the computing architecture of robotic systems, and is an ideal choice when making decisions in real-time. Since FPGAs store configuration data in volatile memory, they are faster than microcontrollers and allow robots to respond quickly to changing conditions. This makes them a great choice for navigation and obstacle avoidance algorithms.
The XCV400E-7BG432I can also be used in medical instruments. The onboard features of the IC are often used to acquire and analyze patient data, which is then used to make informed decisions. The onboard memory of XCV400E-7BG432I is especially helpful in this regard, as it allows for longer data acquisition intervals as well as secure in-built algorithms for data processing. This ensures that the device can reliably perform even in highly demanding medical environments.
In advanced automation systems, XCV400E-7BG432I can be used to control entire systems that require multiple inputs and outputs. This FPGA is used to manage communications between devices, which ensures the system processes data quickly and accurately. Additionally, these FPGAs are also used in industrial control applications, as they can easily integrate a variety of sensors, motors and actuators.
XCV400E-7BG432I Working Principle
The basic design principle of XCV400E-7BG432I is structured around a customer programmable interconnect matrix. This matrix consists of multiple match boxes, or programmable logic cells, that are interconnected by metal pick UP lines. The cells are then connected to input/output (I/O) ports to enable communication with other components. Once the chosen IC is connected to the power source, the customer can then feed it data in order to program the IC for a specific task.
The logic cells are a combination of elements like multiplexers, flip-flops, registers, shift registers and adders. They enable XCV400E-7BG432I to solve large computational problems. Once the data is programmed into the IC, the match boxes can take decisions and route data between the components as required. The FPGA can then use predefined or user-configurable algorithms to process the data and take appropriate decisions.
XCV400E-7BG432I is highly reliable and is able to withstand temperatures of up to 105°C. This makes it ideal for use in industrial and aerospace applications, which require the use of high-temperature materials. It also has a robust architecture and reliable power delivery, making it an excellent choice for applications like medical imaging, industrial control and robotics.
The XCV400E-7BG432I has a wide range of configurations, including multiple I/O ports, on-chip memory and dedicated logic for data acquisition and control. This makes it an extremely versatile FPGA and greatly reduces the complexity of designing embedded systems.
In conclusion, XCV400E-7BG432I is an ideal choice for a wide range of embedded applications. Its versatile configurations, robust architecture and reliable power delivery make it an excellent choice for industries where reliability and accuracy are essential, such as medical imaging, robotics and advanced automation systems.
The specific data is subject to PDF, and the above content is for reference
Part Number | Manufacturer | Price | Quantity | Description |
---|
XCV400-4BG432C | Xilinx Inc. | -- | 1000 | IC FPGA 316 I/O 432MBGA |
XCV400-4BG432I | Xilinx Inc. | -- | 1000 | IC FPGA 316 I/O 432MBGA |
XCV400-4BG560C | Xilinx Inc. | -- | 37 | IC FPGA 404 I/O 560MBGA |
XCV400-4BG560I | Xilinx Inc. | -- | 1000 | IC FPGA 404 I/O 560MBGA |
XCV400-4FG676C | Xilinx Inc. | -- | 1000 | IC FPGA 404 I/O 676FBGA |
XCV400-4FG676I | Xilinx Inc. | -- | 1000 | IC FPGA 404 I/O 676FBGA |
XCV400-4HQ240C | Xilinx Inc. | -- | 1000 | IC FPGA 166 I/O 240HQFP |
XCV400-4HQ240I | Xilinx Inc. | -- | 1000 | IC FPGA 166 I/O 240HQFP |
XCV400-5BG432C | Xilinx Inc. | -- | 1000 | IC FPGA 316 I/O 432MBGA |
XCV400-5BG432I | Xilinx Inc. | -- | 1000 | IC FPGA 316 I/O 432MBGA |
XCV400-5BG560C | Xilinx Inc. | 65.67 $ | 300 | IC FPGA 404 I/O 560MBGA |
XCV400-5BG560I | Xilinx Inc. | -- | 1000 | IC FPGA 404 I/O 560MBGA |
XCV400-5FG676C | Xilinx Inc. | -- | 1000 | IC FPGA 404 I/O 676FBGA |
XCV400-5FG676I | Xilinx Inc. | 0.0 $ | 1000 | IC FPGA 404 I/O 676FBGA |
XCV400-5HQ240C | Xilinx Inc. | 0.0 $ | 1000 | IC FPGA 166 I/O 240HQFP |
XCV400-5HQ240I | Xilinx Inc. | 0.0 $ | 1000 | IC FPGA 166 I/O 240HQFP |
XCV400-6BG432C | Xilinx Inc. | -- | 1000 | IC FPGA 316 I/O 432MBGA |
XCV400-6BG560C | Xilinx Inc. | -- | 1000 | IC FPGA 404 I/O 560MBGA |
XCV400-6FG676C | Xilinx Inc. | -- | 1000 | IC FPGA 404 I/O 676FBGA |
XCV400-6HQ240C | Xilinx Inc. | -- | 1000 | IC FPGA 166 I/O 240HQFP |
XCV400E-6BG432C | Xilinx Inc. | -- | 1000 | IC FPGA 316 I/O 432MBGA |
XCV400E-6BG560C | Xilinx Inc. | 0.0 $ | 1000 | IC FPGA 404 I/O 560MBGA |
XCV400E-6BG560I | Xilinx Inc. | 0.0 $ | 1000 | IC FPGA 404 I/O 560MBGA |
XCV400E-6FG676C | Xilinx Inc. | -- | 1000 | IC FPGA 404 I/O 676FBGA |
XCV400E-6FG676I | Xilinx Inc. | 0.0 $ | 1000 | IC FPGA 404 I/O 676FBGA |
XCV400E-6PQ240C | Xilinx Inc. | -- | 1000 | IC FPGA 158 I/O 240QFP |
XCV400E-6PQ240I | Xilinx Inc. | 65.67 $ | 3 | IC FPGA 158 I/O 240QFP |
XCV400E-7BG432C | Xilinx Inc. | 0.0 $ | 1000 | IC FPGA 316 I/O 432MBGA |
XCV400E-7BG432I | Xilinx Inc. | -- | 1000 | IC FPGA 316 I/O 432MBGA |
XCV400E-7BG560C | Xilinx Inc. | -- | 60 | IC FPGA 404 I/O 560MBGA |
XCV400E-7BG560I | Xilinx Inc. | 0.0 $ | 1000 | IC FPGA 404 I/O 560MBGA |
XCV400E-7FG676C | Xilinx Inc. | -- | 1000 | IC FPGA 404 I/O 676FBGA |
XCV400E-7FG676I | Xilinx Inc. | 0.0 $ | 1000 | IC FPGA 404 I/O 676FBGA |
XCV400E-7PQ240C | Xilinx Inc. | 0.0 $ | 1000 | IC FPGA 158 I/O 240QFP |
XCV400E-7PQ240I | Xilinx Inc. | 0.0 $ | 1000 | IC FPGA 158 I/O 240QFP |
XCV400E-8BG432C | Xilinx Inc. | 0.0 $ | 1000 | IC FPGA 316 I/O 432MBGA |
XCV400E-8BG560C | Xilinx Inc. | 0.0 $ | 1000 | IC FPGA 404 I/O 560MBGA |
XCV400E-8FG676C | Xilinx Inc. | -- | 1000 | IC FPGA 404 I/O 676FBGA |
XCV400E-8PQ240C | Xilinx Inc. | 0.0 $ | 1000 | IC FPGA 158 I/O 240QFP |
XCV405E-6BG560C | Xilinx Inc. | 90.29 $ | 7 | IC FPGA 404 I/O 560MBGA |
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