EP1AGX35CF484C6N vs 5CEFA7F23C6N
| Part Number |
|
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| Category | Embedded - FPGAs (Field Programmable Gate Array) | Embedded - FPGAs (Field Programmable Gate Array) |
| Manufacturer | Intel | Intel |
| Description | IC FPGA 230 I/O 484FBGA | IC FPGA 240 I/O 484FBGA |
| Package | 484-BBGA | 484-BGA |
| Series | Arria GX | Cyclone® V E |
| Voltage - Supply | 1.15 V ~ 1.25 V | 1.07 V ~ 1.13 V |
| Operating Temperature | 0°C ~ 85°C (TJ) | 0°C ~ 85°C (TJ) |
| Mounting Type | Surface Mount | Surface Mount |
| Package / Case | 484-BBGA | 484-BGA |
| Supplier Device Package | 484-FBGA (23x23) | 484-FBGA (23x23) |
| Number of I/O | 230 | 240 |
| Number of LABs/CLBs | 1676 | 56480 |
| Number of Logic Elements/Cells | 33520 | 149500 |
| Total RAM Bits | 1348416 | 7880704 |
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1. What is the hardware of FPGA?
FPGA (Field-Programmable Gate Array) is a hardware device, not software. FPGA is a programmable hardware device consisting of a large number of logic units, storage units and interconnection resources, which can realize complex digital circuits and system designs.
The hardware structure of FPGA mainly includes the following parts:
Logic unit: FPGA contains programmable logic blocks that can perform logical and arithmetic operations.
Interconnection resources: These resources act as connections between logic blocks, allowing data to be transferred between different logic blocks.
Memory unit: Used to store configuration information and temporary data, supporting FPGA operations and logic processing.
The characteristics and application scenarios of FPGA include:
Programmability: FPGA can change the structure of its internal circuits by loading configuration information to achieve different functions.
High-speed execution: FPGA performs logic operations at the hardware level, which is usually several orders of magnitude faster than software execution.
Wide application: FPGA is widely used in many fields such as communications, medical, automotive, aerospace, industrial automation, etc. to implement complex digital circuits and algorithms, improve equipment performance, reduce power consumption or achieve specific functional requirements. -
2. What is the hardware of FPGA?
FPGA (Field Programmable Gate Array) is a highly flexible programmable logic chip that users can program to achieve specific logic functions according to their needs. The main uses of FPGA include communications and networks, digital signal processing, automotive and aerospace, industrial automation, high-performance computing, smart Internet of Things and many other aspects.
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3. Is FPGA a microcontroller?
FPGA is not a microcontroller. There are significant differences between FPGA and microcontroller in terms of function and use.
FPGA is a programmable integrated circuit, which is programmed through hardware description language and can customize the circuit according to needs. It is very suitable for application scenarios that require flexible configuration and high performance. In contrast, microcontrollers (MCUs) are integrated circuits with preset functions, usually used for single tasks and requiring efficient execution.
FPGAs and MCUs also differ in structure and application scenarios. FPGAs offer great flexibility and are suitable for complex applications that require rapid prototyping and reconfigurability. On the other hand, MCUs combine processor cores, memory, and various peripherals in a single chip, designed for specific tasks, and provide cost-effective solutions. -
4. Why use FPGA as a digital controller?
The main reason for using FPGA as a digital controller is its flexibility and programmability. FPGA (Field Programmable Gate Array) is a chip whose internal structure can be changed through programming. It has high flexibility and programmability, which makes FPGA widely used in the field of digital controllers.
The flexibility of FPGA is reflected in the fact that its logic units can be configured to implement different logic functions. Users can use hardware description languages (such as VHDL or Verilog) to write programs to map logic functions to lookup tables (LUTs) and logic units inside FPGA. This flexibility allows FPGAs to adapt to different application requirements and can be reprogrammed as needed to adapt to new application scenarios.
In addition, FPGAs also have high-performance parallel computing capabilities and high-speed data processing capabilities, which makes it play an important role in digital signal processing, image processing, network communication and other fields. The parallel processing capabilities of FPGAs enable it to handle multiple tasks at the same time, improving overall processing efficiency.
