The TC74VCX16374(ELF) is a 16-bit D-type flip-flop with a 3.6V tolerant input and output manufactured by Toshiba Semiconductor and Storage. This device is designed for high-performance bus interface applications requiring minimal propagation delay. It features advanced CMOS technology, enabling low power consumption and high-speed operation. The TC74VCX16374 incorporates non-inverting buffers, providing true data transmission. It's housed in a TSSOP package, suitable for surface mount assembly.

Applications:

• High-speed data transfer systems
• Memory interface applications
• Clocked data registers
• Bus interface in microprocessor-based systems
• High-performance computing

Features:

• 3.6V Tolerant Inputs and Outputs
• Low Voltage Operation: 1.65V to 3.6V
• High-Speed Operation: tpd = 2.5 ns (typical) at 3.3V
• Low Power Consumption: ICC = 4 μA (maximum) at 3.6V
• Non-Inverting Outputs
• Output Drive Capability: IOL = 24 mA at 3.3V, IOH = -24 mA at 3.3V
• TSSOP Package for space-saving design

Benefits:

• Enhanced System Performance: Fast propagation delay minimizes data transfer times, improving overall system speed.
• Reduced Power Consumption: Low power consumption leads to extended battery life in portable devices and reduced energy costs in other applications.
• Simplified System Design: 3.6V tolerant inputs and outputs allow for seamless integration with other devices operating at different voltage levels.
• High Drive Capability: Ensures reliable signal transmission over longer distances or to multiple devices.
• Space-Saving Design: The TSSOP package allows for higher component density on the PCB.

Additional Details:

The TC74VCX16374 is ideal for applications requiring high-speed data transfer and low power consumption. The device's 3.6V tolerant inputs and outputs make it suitable for mixed-voltage systems. Its high output drive capability ensures robust signal transmission. This flip-flop provides eight non-inverting D-type flip-flops with 3-state outputs. The device is controlled by a clock (CLK) input and an output enable (OE) input. When OE is low, the flip-flops transfer data to the outputs. When OE is high, the outputs are in the high-impedance state. The device operates over a wide temperature range, making it suitable for various environments.