Allicdata Part #: | 544-2536-ND |
Manufacturer Part#: |
EP3C10F256I7N |
Price: | $ 656.71 |
Product Category: | Integrated Circuits (ICs) |
Manufacturer: | Intel FPGAs/Altera |
Short Description: | IC FPGA 182 I/O 256FBGA |
More Detail: | N/A |
DataSheet: | EP3C10F256I7N Datasheet/PDF |
Quantity: | 100 |
Lead Free Status / RoHS Status: | Lead free / RoHS Compliant |
Moisture Sensitivity Level (MSL): | 3 (168 Hours) |
1 +: | $ 656.71000 |
Series: | Cyclone® III |
Part Status: | Active |
Lead Free Status / RoHS Status: | -- |
Number of LABs/CLBs: | 645 |
Moisture Sensitivity Level (MSL): | -- |
Number of Logic Elements/Cells: | 10320 |
Total RAM Bits: | 423936 |
Number of I/O: | 182 |
Voltage - Supply: | 1.15 V ~ 1.25 V |
Mounting Type: | Surface Mount |
Number of Gates: | -- |
Operating Temperature: | -40°C ~ 100°C (TJ) |
Package / Case: | 256-LBGA |
Supplier Device Package: | 256-FBGA (17x17) |
Base Part Number: | EP3C10 |
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Introduction to Embedded FPGAs
An FPGA (Field Programmable Gate Array) is a type of integrated circuit that can be used to design and implement logic circuits, as well as to control timing, memory, and communications in embedded systems. FPGAs are appealing to embedded applications because they are much more efficient than traditional application-specific integrated circuits (ASICs). FPGA technology generally achieves better performance than ASICs since it can be programmed to target a wide range of applications quickly, without the need for expensive custom ASIC development.The EP3C10F256I7N is an FPGA from Altera Corporation. With an impressive 10 million logic elements, and up to 256 I/O pins, this FPGA contains enough power to design logic/timer/memory control for a wide range of embedded applications. The EP3C10F256I7N utilizes Altera's MAX 10 device family, providing a scalable, feature-rich embedded FPGA.
Benefits of FPGA Technology
FPGA technology provides several advantages over traditional ASICs, making them an attractive choice for embedded applications. One major benefit of an FPGA is its ability to reconfigure itself to adjust to new or changing requirements. This means that an FPGA can be reprogrammed or updated remotely, at any phase in the development process. This makes FPGAs very flexible and cost effective.Another major advantage is the speed at which FPGAs can design and implement logic circuits. FPGAs generally require less engineering time to create and program logic than traditional ASICs. This can lead to reduced cost and shortened development cycles. Additionally, FPGAs are more reliable than their ASIC counterparts, offering higher system reliability for embedded applications.
EP3C10F256I7N Features
The EP3C10F256I7N features Altera’s MAX 10 device family, enabling customizable embedded systems with low power and low cost. These devices offer enhanced system integration capabilities to address performance, density and low-power requirements. The EP3C10F256I7N has up to 10 million logic elements divided into rows and columns, with each column having 4 logic elements. It also has up to 256 Input/Output (I/O) pins which can be configured for various signal speeds, such as Serial Peripheral Interfaces (SPI) and Universal Serial Bus (USB). These I/O pins also provide access to on-chip signal processing blocks (eg. Arithmetic Blocks and Logic Blocks).Other features of the EP3C10F256I7N include up to 32 Megabits of on-chip RAM, as well as on-chip oscillators, pull-up resistors, and pull-down resistors. This FPGA also offers error detection and correction, soft error protection, and enhanced power management.
Applications of EP3C10F256I7N
The EP3C10F256I7N is suitable for a wide range of embedded applications, including consumer applications such as television sets, automotive systems, factory automation systems, and medical devices. This FPGA is also suitable for telecommunications, security systems, and industrial automation applications, where ultra-low power is a primary concern.The EP3C10F256I7N FPGA provides enough power for advanced experiments such as 3D visual simulation, vehicle-to-infrastructure communication systems, and data encryption, making it ideal for a variety of research applications.
Conclusion
The EP3C10F256I7N is an impressive FPGA that offers enough power to design logic/timer/memory control for a wide range of embedded applications. The FPGA provides several benefits over traditional ASICs, including reconfigurability, reduced engineering time, increased reliability, and enhanced power management. The EP3C10F256I7N is suitable for many applications, including consumer, telecommunications, security, and industrial applications.
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Part Number | Manufacturer | Price | Quantity | Description |
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EP3C16Q240C8 | Intel FPGAs/... | -- | 127 | IC FPGA 160 I/O 240QFP |
EP3C16U256C8N | Intel FPGAs/... | 246.26 $ | 200 | IC FPGA 168 I/O 256UBGA |
EP3C16E144C7N | Intel FPGAs/... | -- | 1000 | IC FPGA 84 I/O 144EQFP |
EP3C16F484I7N | Intel FPGAs/... | 492.53 $ | 10 | IC FPGA 346 I/O 484FBGA |
EP3C10U256C8N | Intel FPGAs/... | -- | 65 | IC FPGA 182 I/O 256UBGA |
EP3C16E144C8 | Intel FPGAs/... | -- | 120 | IC FPGA 84 I/O 144EQFP |
EP3C25F324C7N | Intel FPGAs/... | -- | 84 | IC FPGA 215 I/O 324FBGA |
EP3C80F780C8N | Intel FPGAs/... | -- | 35 | IC FPGA 429 I/O 780FBGA |
EP3C5F256C8N | Intel FPGAs/... | -- | 969 | IC FPGA 182 I/O 256FBGA |
EP3C5E144C8N | Intel FPGAs/... | -- | 2358 | IC FPGA 94 I/O 144EQFP |
EP3C5E144C7N | Intel FPGAs/... | -- | 961 | IC FPGA 94 I/O 144EQFP |
EP3C5F256C7N | Intel FPGAs/... | 15.51 $ | 355 | IC FPGA 182 I/O 256FBGA |
EP3C5E144I7N | Intel FPGAs/... | -- | 1029 | IC FPGA 94 I/O 144EQFP |
EP3C10E144C8N | Intel FPGAs/... | -- | 341 | IC FPGA 94 I/O 144EQFP |
EP3C10E144C7N | Intel FPGAs/... | 344.77 $ | 1 | IC FPGA 94 I/O 144EQFP |
EP3C10F256C8N | Intel FPGAs/... | 197.01 $ | 13 | IC FPGA 182 I/O 256FBGA |
EP3C16E144C8N | Intel FPGAs/... | -- | 89 | IC FPGA 84 I/O 144EQFP |
EP3C5F256I7N | Intel FPGAs/... | -- | 990 | IC FPGA 182 I/O 256FBGA |
EP3C5F256C6N | Intel FPGAs/... | -- | 1000 | IC FPGA 182 I/O 256FBGA |
EP3C10F256C7N | Intel FPGAs/... | -- | 131 | IC FPGA 182 I/O 256FBGA |
EP3C10E144I7N | Intel FPGAs/... | 221.64 $ | 1 | IC FPGA 94 I/O 144EQFP |
EP3C16Q240C8N | Intel FPGAs/... | -- | 1042 | IC FPGA 160 I/O 240QFP |
EP3C16F256C8N | Intel FPGAs/... | -- | 1 | IC FPGA 168 I/O 256FBGA |
EP3C5U256C6N | Intel FPGAs/... | -- | 106 | IC FPGA 182 I/O 256UBGA |
EP3C16F484C8N | Intel FPGAs/... | -- | 436 | IC FPGA 346 I/O 484FBGA |
EP3C10F256I7N | Intel FPGAs/... | 656.71 $ | 100 | IC FPGA 182 I/O 256FBGA |
EP3C10F256C6N | Intel FPGAs/... | -- | 126 | IC FPGA 182 I/O 256FBGA |
EP3C10U256I7N | Intel FPGAs/... | -- | 290 | IC FPGA 182 I/O 256UBGA |
EP3C16F484C7N | Intel FPGAs/... | 34.56 $ | 108 | IC FPGA 346 I/O 484FBGA |
EP3C25Q240C8N | Intel FPGAs/... | -- | 425 | IC FPGA 148 I/O 240QFP |
EP3C16M164I7N | Intel FPGAs/... | -- | 1000 | IC FPGA 92 I/O 164MBGA |
EP3C16F256I7N | Intel FPGAs/... | 492.53 $ | 1000 | IC FPGA 168 I/O 256FBGA |
EP3C16F256C6N | Intel FPGAs/... | -- | 122 | IC FPGA 168 I/O 256FBGA |
EP3C25F256C8N | Intel FPGAs/... | -- | 1000 | IC FPGA 156 I/O 256FBGA |
EP3C25U256C8N | Intel FPGAs/... | -- | 144 | IC FPGA 156 I/O 256UBGA |
EP3C25F324C8N | Intel FPGAs/... | -- | 1074 | IC FPGA 215 I/O 324FBGA |
EP3C16F484C6N | Intel FPGAs/... | 394.02 $ | 1 | IC FPGA 346 I/O 484FBGA |
EP3C25E144I7N | Intel FPGAs/... | -- | 297 | IC FPGA 82 I/O 144EQFP |
EP3C25F256I7N | Intel FPGAs/... | -- | 212 | IC FPGA 156 I/O 256FBGA |
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