The SN74LV175ADR is a high-performance, quad D-type flip-flop integrated circuit (IC) designed and manufactured by Texas Instruments (TI). This device is part of TI's advanced low-voltage (LV) CMOS logic family, which is renowned for its low-power consumption and high-speed operation.

Key Features

• Voltage Range: The SN74LV175ADR operates at a wide voltage range from 2V to 5.5V, making it suitable for interfacing with both TTL and CMOS logic levels.
• High Speed: With a typical tpd of 6.5ns (max), it provides rapid response times, which is essential for high-speed data processing applications.
• Low Power Consumption: It has a low ICC of 20µA max, which helps to minimize power consumption in battery-powered or power-sensitive applications.
• Output Drive Capability: The IC can drive up to 24mA at the output, allowing it to control LEDs or other light loads without the need for additional buffer components.
• Edge-Triggered: The flip-flops are positive-edge triggered, capturing data on the rising edge of the clock signal, which simplifies timing design.

Applications

The SN74LV175ADR is versatile and can be used in various digital applications such as:

• Data storage and retrieval systems
• Shift registers
• System control registers
• Counters and dividers

Package and Quality

This IC is available in a 16-pin SOIC package, designated by the suffix 'ADR', which is suitable for surface-mount technology (SMT) assembly processes. The SN74LV175ADR is also characterized for operation from -40°C to 85°C, ensuring reliable performance across a wide range of environmental conditions.

Part Numbering Information

The full part number SN74LV175ADR indicates the specific product configuration:

• SN74 - Texas Instruments High-Speed CMOS Logic Family
• LV - Low-Voltage Series
• 175 - Specific Device Number (Quad D-Type Flip-Flop)
• A - Advanced High-Speed CMOS
• DR - Tape and Reel Packaging for SOIC

With its robust design and versatile features, the SN74LV175ADR is a reliable choice for designers looking to implement flip-flops in their digital circuit designs.