|
Images
|
Mfr.Part #
|
In Stock
|
Manufacturer
|
Description
|
Package
|
|---|---|---|---|---|---|
|
LC4256C-3FN256AC | 32355 | Lattice Semiconductor Corporation | IC CPLD 256MC 3NS 256FPBGA | 256-BGA |
|
LC4256ZE-7TN100C | 31629 | Lattice Semiconductor Corporation | IC CPLD 256MC 7.5NS 100TQFP | 100-LQFP |
|
|
LC5512B-75F256C | 46786 | Lattice Semiconductor Corporation | IC CPLD 512MC 7.5NS 256FPBGA | 256-BGA |
|
|
LC4256C-5FN256BC | 14597 | Lattice Semiconductor Corporation | IC CPLD 256MC 5NS 256FPBGA | 256-BGA |
|
GAL16V8-25QVC | 7027 | National Semiconductor | IC CPLD 8MC 25NS 20PLCC | 20-LCC (J-Lead) |
|
EPM7064QC100-10 | 46584 | Altera | IC CPLD 64MC 10NS 100QFP | 100-BQFP |
|
EP900JM | 33213 | Altera | IC PLD 24MC 55NS 40JLCC | Bulk |
|
EP324DC-25 | 32630 | Altera | IC PLD 24MC 25NS 40CDIP | 40-CDIP (0.600", 15.24mm) |
|
|
LC4256V-5F256AC | 17429 | Lattice Semiconductor Corporation | IC CPLD 256MC 5NS 256FPBGA | 256-BGA |
|
|
LC4256C-5F256BC | 50284 | Lattice Semiconductor Corporation | IC CPLD 256MC 5NS 256FPBGA | 256-BGA |
|
EPM7064BFC100-5 | 11755 | Altera | IC CPLD 64MC 5NS 100FBGA | 100-LBGA |
|
ISPLSI2128VL-150LB100 | 43929 | Lattice Semiconductor Corporation | IC CPLD 128MC 6NS 100CABGA | 100-LFBGA |
|
|
LC4256B-5F256BC | 21806 | Lattice Semiconductor Corporation | IC CPLD 256MC 5NS 256FPBGA | 256-BGA |
|
|
LC5512MC-75F256C | 19016 | Lattice Semiconductor Corporation | IC CPLD 512MC 7.5NS 256FPBGA | 256-BGA |
|
|
EP910ILI-12 | 24971 | Altera | IC PLD 16MC 12NS 28PLCC | 28-LCC (J-Lead) |
|
ISPGDX160VA-9B272I | 45371 | Lattice Semiconductor Corporation | EE PLD, 9NS, CMOS, PBGA272 | 272-BBGA |
|
|
EPM7128BFC256-7 | 58879 | Altera | IC CPLD 128MC 7.5NS 256FBGA | 256-BGA |
|
ISPLSI1048E-50LQ | 31958 | Lattice Semiconductor Corporation | IC CPLD 192MC 20NS 128QFP | 128-BQFP |
|
|
LC4384V-5FN256C | 52092 | Lattice Semiconductor Corporation | IC CPLD 384MC 5NS 256FPBGA | 256-BGA |
|
HPL1-16RC6-2 | 40869 | Harris Corporation | IC PLD 125NS 20DIP | 20-DIP (0.300", 7.62mm) |
CPLDs (Complex Programmable Logic Devices)
1. What are Complex Programmable Logic Devices?
CPLD (Complex Programmable Logic Device) is a digital integrated circuit with user-defined logic functions. It was developed from the early PAL (Programmable Array Logic) and GAL (General Array Logic) and belongs to the category of large-scale integrated circuits. It was born in the mid-1980s to make up for the defect that early PLD devices could not realize complex circuits.
2. What are the Core Structural Features of Complex Programmable Logic Devices?
Logic Unit: It is composed of multiple programmable logic macrocells (Macro Cells). Each macrocell can process dozens of combinational logic inputs and is suitable for implementing complex combinational logic such as decoders.
Interconnection Resources: Logic units are connected through a central programmable interconnect matrix to provide flexible wiring capabilities.
I/O Resources: It integrates rich input/output pins and supports an efficient interface with external circuits.
3. What are the Technical Features of Complex Programmable Logic Devices?
Programming Technology: It adopts non-volatile storage technology based on EEPROM or Flash. After programming, data will not be lost when power is off, and it supports multiple updates in-system programming (ISP).
Performance Advantages: It has the characteristics of high-density integration, low power consumption, and high reliability, and is suitable for scenarios with high real-time requirements.
4. What are the Key Differences from FPGA?
|
Features |
CPLD |
FPGA |
|
Structural Basis |
Product term technology, macrocell structure |
Lookup table technology (LUT) |
|
Configuration Storage |
On-chip integrated EEPROM/Flash |
External configuration memory required |
|
Applicable Scenarios |
Complex combinational logic, control intensive |
Data-intensive, high-performance computing |
|
Granularity |
Large granularity (macrocell level) |
Medium granularity (LUT level) |
5. What are the Application Advantages of Complex Programmable Logic Devices?
Development Efficiency: Rapid design through schematics or hardware description language (HDL), shortening the development cycle and lowering the hardware experience threshold.
Cost-effectiveness: No tape-out cost, suitable for small and medium-scale production (such as less than 10,000 pieces) and prototype verification.
Flexibility: Repeatable programming to modify logic functions, widely used in communications, industrial control, automotive electronics, and other fields.
As a key component in digital system design, CPLD balances flexibility, integration, and cost, and is the preferred solution for the implementation of small and medium-scale logic circuits.