5CEBA4F17I7

Due to market price fluctuations, if you need to purchase or consult the price. You can contact us or emial to us:   sales@allicdata.com

Embedded Field Programmable Gate Arrays (FPGAs) is an integrated circuit which consists of configurable digital logic blocks. They are programmable by external programming devices to implement user-specified logic functions and store them into their internal memory. Such FPGAs can be seen as the platforms that are used to design different types of digital systems including high speed signal processing and telecom systems, the 5CEBA4F17I7 application field and working principle is no exception.

The 5CEBA4F17I7 Field Programmable Gate Array (FPGA) is an Altera product family targeting high speed signal processing, telecom and general purpose embedded application. Its application field includes automotive, medical imaging, transportation, industrial automation and various other embedded applications.

The 5CEBA4F17I7 FPGA has an integrated logic element (LE) with the support of technologies such as the Enhanced SystemPack and SmartARRAY. It features high performance hard system integration capability, multi-GHz signal processing, advanced resource sharing through DUAL-ARRAY (DPA) architecture and extended temperature operating.

The working principle of the 5CEBA4F17I7 FPGA is based on the Field Programmable Gate Array (FPGA) technology. This involves configurable blocks of digital logic (called logic elements or LEs) that are interconnected to produce a desired logic function. The logic elements can be configured using external programming devices (called programmer) and stored into the internal memory of the FPGA. The programmer allows creating custom designs as well as storing these designs to be reused in the future.

In terms of power efficiency, the 5CEBA4F17I7 FPGA supports highly efficient power dissipation designs through the use of dynamic voltage frequency scaling (DVFS) technique and cascade logic architecture. Additionally, the 5CEBA4F17I7 FPGA is equipped with power on reset (POR) and brown out reset (BOR) which provides protection from voltage transients and short circuits.

To add to its power efficiency, the 5CEBA4F17I7 FPGA also utilizes clock gating technique which helps to reduce power consumption. This technique enables the FPGA to logically switch off part of the clock by shutting off the clock to the non-essential logic elements in order to conserve the power usage.

The 5CEBA4F17I7 FPGA also features compression and decompression capability through the use of high density Altera compression blocks, which allows higher data transfer rates without sacrificing significant energy usage. This helps minimize power consumption while achieving high throughput data transfer.

The 5CEBA4F17I7 FPGA also has advanced memory and on-chip embedded memory support, which provide high performance capabilities along with low power consumption. This is achieved through advanced memory management techniques, such as aggressive bank assignments and an integrated dual-ported SRAMi core. The dual-ported SRAMi core makes possible the creation of low latency memories with wider data width and higher clock rates.

In terms of safety, the 5CEBA4F17I7 FPGA is equipped with advanced fault detection and fault recovery mechanisms. This helps to detect any unexpected conditions or errors in the system and quickly recover from them, restoring system to its normal operating state. Additionally, the 5CEBA4F17I7 FPGA supports various on-chip embedded debug and trace capabilities.

Overall, the 5CEBA4F17I7 Field Programmable Gate Array FPGA is a cost-effective and energy-efficient product with advanced tools and peripherals for embedded applications. With its support for dynamic voltage frequency scaling, advanced memory, embedded debug and trace capabilities, and fault detection and fault recovery mechanisms, the 5CEBA4F17I7 FPGA provides users with a reliable and versatile platform for their embedded applications.

The specific data is subject to PDF, and the above content is for reference