Texas Instruments SN74LVC2G240DCUR Dual Tri-State Buffer, SOT-23-8 ?C Low-Voltage Logic

SN74LVC2G240DCUR Low-Voltage Dual Tri-State Buffer Overview

The SN74LVC2G240DCUR from Texas Instruments is a compact, dual-channel (2-channel) tri-state buffer designed to isolate and amplify digital signals in low-voltage electronic systems. Its tri-state outputs??high, low, or high-impedance??enable safe disconnection from shared buses, preventing signal conflicts in multi-device setups. This makes it ideal for IoT sensors, wearables, and industrial interfaces where reliable dual-path communication and noise immunity are critical. IC-fabrikant biedt deze essentiële logische component als onderdeel van zijn portfolio van halfgeleiders met laag stroomverbruik, vertrouwd voor prestaties in ontwerpen met beperkte ruimte.

Technical Parameters of SN74LVC2G240DCUR

Operationele kenmerken

Voordelen ten opzichte van alternatieve logische buffers

The SN74LVC2G240DCUR outperforms conventional solutions in dual-channel systems, starting with its integrated design. Unlike using two single-channel tri-state buffers, it reduces component count by 50%, slashing PCB space and assembly costs??critical for devices like IoT sensor hubs with paired temperature and motion sensors. This integration also ensures matched propagation delays across both channels, avoiding timing mismatches in coordinated systems. “We reduced our sensor module size by 15% using this dual buffer instead of two discrete components,” notes a senior engineer at a leading IoT device manufacturer.

Compared to non-tri-state alternatives, its high-impedance mode prevents bus contention in shared architectures (e.g., I2C buses with multiple peripherals), reducing data errors by up to 40%. This is far more reliable than basic buffers, which can cause signal collisions in multi-master setups common in industrial automation.

Its 1.65V?C3.6V voltage range supports modern low-power standards (1.8V microcontrollers, 3.3V sensors) better than older logic families (e.g., 74HC), which require higher voltages. This versatility allows manufacturers to standardize on one component across product lines, simplifying inventory. At 1??A quiescent current, it also balances power efficiency with dual-channel functionality, outperforming discrete solutions by 40% in standby power draw.

The SOT-23-8 package (3.0mm??3.0mm) fits into space-constrained devices where larger packages (e.g., SOIC-14) won??t work, such as wireless earbuds or medical wearables. Its surface-mount design enables automated assembly, improving manufacturing consistency??critical for high-volume production.

Typical Applications of SN74LVC2G240DCUR

The SN74LVC2G240DCUR excels in dual-channel, low-power systems requiring bus isolation. Key use cases include:

• IoT sensor nodes (isolating paired sensors??e.g., humidity and pressure??on shared buses)
• Wearable electronics (smartwatch communication between dual biometric sensors and processing units)
• Industrial automation (small-scale sensor arrays with 2 independent data paths)
• Consumer electronics (smartphone accessory ports with dual data lines, e.g., charging and audio)
• Medical devices (portable monitors with 2 sensor inputs requiring noise-free communication)

Texas Instruments?? Expertise in laagspanningslogica

As a Texas Instruments product, the SN74LVC2G240DCUR leverages TI??s decades of innovation in low-voltage logic. TI??s LVC series is renowned for balancing isolation, speed, and reliability??critical for modern electronics. Each unit undergoes rigorous testing to withstand -40??C to +85??C temperatures and voltage fluctuations, ensuring performance in harsh environments. This commitment has made TI a trusted partner for brands like Bosch and Apple, who rely on components like the SN74LVC2G240DCUR for consistent performance in high-volume production.

Veelgestelde vragen (FAQ)

What is a dual tri-state buffer, and how does it benefit system design?

A dual tri-state buffer contains two independent tri-state circuits in one package, enabling simultaneous isolation of two signals. This eliminates the need for two separate single-channel ICs, reducing PCB space by up to 50% in dual-path systems (e.g., a smartwatch processing heart rate and motion data). It also ensures matched performance across channels, preventing timing skew in coordinated applications.

Why is 32mA output current per channel important for signal integrity?

32mA output current allows each channel to drive signals over long PCB traces (up to 20cm) or multiple loads without degradation??critical in systems where components are spread across a board, such as industrial sensor arrays or consumer electronics. This prevents voltage drops that could corrupt data, unlike lower-current buffers that may suffer from signal loss in extended layouts.

How does the SOT-23-8 package benefit compact device design?

The SOT-23-8 package??s small footprint (3.0mm??3.0mm) fits in ultra-slim devices like wireless earbuds or glucose monitors, where space is limited by batteries, displays, or other components. Its low profile (1.1mm) supports slim enclosures, while surface-mount technology enables automated assembly??key for high-volume production of consumer and medical devices where miniaturization is critical.

What makes the 1.65V?C3.6V voltage range suitable for mixed-voltage systems?

This range covers the most common low-voltage standards in modern electronics: 1.8V (microcontrollers), 2.5V (DSPs), and 3.3V (sensors). Unlike fixed-voltage buffers, it works across these standards, eliminating the need for multiple components in mixed-voltage designs??such as a 3.3V microcontroller communicating with a 2.5V sensor. This simplifies engineering and reduces costs for manufacturers.

Why is low quiescent current (1??A) important for battery-powered devices?

At 1??A max, the SN74LVC2G240DCUR uses minimal power when idle, directly extending battery life in portables. For example, a wireless sensor node using this buffer might operate for 20 months on a coin cell, vs. 15 months with two single-channel buffers drawing 1??A each. This is especially valuable in remote devices (e.g., agricultural sensors) where frequent battery replacement is impractical.