The EP910LC-30T is a complex programmable logic device (CPLD) manufactured by Rochester Electronics. As a CPLD, it provides a flexible platform for implementing custom digital logic circuits. Rochester Electronics specializes in providing continued support for mature and end-of-life components, ensuring availability for long-lifecycle applications.

Applications:

• Address Decoding
• Glue Logic
• State Machines
• Peripheral Controllers
• Interface Logic

Features:

• CPLD Architecture: Provides flexible logic implementation using programmable AND/OR arrays.
• High-Speed Performance: Designed for high-speed digital logic applications.
• Non-Volatile Configuration: Retains its configuration even when power is removed.
• In-System Programmability (ISP): Allows for easy programming and reprogramming without removing the device from the circuit board.
• Low Power Consumption: Suitable for battery-powered and energy-sensitive applications.
• Wide Operating Voltage Range

Benefits:

• Flexibility: CPLD architecture allows for implementing a wide variety of digital logic circuits.
• High Performance: High-speed performance ensures that the device can keep up with demanding applications.
• Ease of Programming: In-system programmability simplifies development and allows for easy updates.
• Non-Volatile Configuration: Ensures that the device retains its configuration even when power is removed.
• Continued Availability: Rochester Electronics ensures continued availability of this device, even after the original manufacturer has discontinued production.

Additional Details:

The EP910LC-30T is typically programmed using industry-standard programming tools. It is a non-volatile device, meaning that it retains its configuration even when power is removed. The in-system programmability (ISP) feature allows for easy programming and reprogramming without removing the device from the circuit board. This can be particularly useful for prototyping and debugging. The device is designed for a wide operating voltage range for versatile implementations.