Product Specification
The XCS20-3PQG208C features a robust architecture optimized for demanding applications. This FPGA delivers high logic density with excellent power efficiency, enabling designers to implement complex algorithms and processing functions. The device operates across a wide temperature range, ensuring reliable performance in various environmental conditions.
Key technical specifications include advanced programmable logic cells, dedicated memory blocks, and high-speed I/O capabilities. The XCS20-3PQG208C supports multiple voltage standards and includes built-in clock management resources for precise timing control. Its 208-pin PQFP package provides optimal pin density while maintaining excellent signal integrity.
The device incorporates advanced features such as embedded multipliers, distributed RAM, and flexible routing architecture. These capabilities enable efficient implementation of digital filters, communication protocols, and custom processing algorithms. The XCS20-3PQG208C also includes comprehensive debugging and configuration options to streamline development workflows.
Price
Pricing for the XCS20-3PQG208C varies based on order quantity, packaging requirements, and delivery specifications. Volume discounts are available for large-scale production requirements. Contact authorized distributors for current pricing information and availability status.
The cost-effective nature of the XCS20-3PQG208C makes it suitable for both prototype development and high-volume manufacturing. Educational discounts may be available for qualifying institutions and research organizations.
Documents & Media
Comprehensive technical documentation is available for the XCS20-3PQG208C, including detailed datasheets, application notes, and design guides. These resources provide essential information for successful implementation and optimization of FPGA-based designs.
Available documentation includes pin configuration diagrams, timing specifications, power consumption guidelines, and recommended PCB layout practices. Development tools and software packages are also provided to support the complete design flow from specification to deployment.
Video tutorials and webinar recordings offer additional learning resources for engineers working with the XCS20-3PQG208C. These materials cover topics ranging from basic configuration to advanced optimization techniques.
Related Resources
The XCS20-3PQG208C is supported by a comprehensive ecosystem of development tools, IP cores, and reference designs. Compatible development boards and evaluation kits enable rapid prototyping and proof-of-concept development.
Software development environments provide integrated design entry, synthesis, and debugging capabilities specifically optimized for the XCS20-3PQG208C architecture. Third-party IP libraries extend functionality with pre-verified modules for common applications.
Community forums and technical support resources offer assistance throughout the development process. Application engineers provide specialized guidance for complex implementation challenges and optimization requirements.
Environmental & Export Classifications
The XCS20-3PQG208C meets stringent environmental and quality standards required for commercial and industrial applications. RoHS compliance ensures environmental responsibility, while automotive-grade variants are available for demanding automotive applications.
Export classification information is available for international shipping and regulatory compliance. The device complies with relevant electromagnetic compatibility (EMC) standards and safety regulations for global market deployment.
Temperature ratings support operation in extended environmental conditions, making the XCS20-3PQG208C suitable for outdoor, automotive, and industrial applications. Reliability testing ensures consistent performance throughout the product lifecycle.
The XCS20-3PQG208C represents an excellent balance of performance, flexibility, and cost-effectiveness for modern FPGA applications. Its comprehensive feature set and robust support ecosystem make it an ideal choice for engineers developing next-generation electronic systems.
