ON Semiconductor NL17SZ126DFT2G - Non-Inverting Buffer with 3-State Output

The NL17SZ126DFT2G is a high-performance, non-inverting buffer designed by ON Semiconductor, which features a 3-state output to facilitate connection to a bus-structured system. This integrated circuit is part of ON Semiconductor's NL17SZ series, renowned for its low power consumption and high-speed operation. It is an ideal choice for a wide range of applications, including signal buffering and bus driving, where power efficiency and speed are critical.

This device is capable of operating within a voltage range of 1.65V to 5.5V, which makes it compatible with TTL levels and suitable for interfacing with both 3.3V and 5V systems. The low dynamic power consumption, coupled with a high noise immunity, ensures a robust performance in various electronic circuits. The NL17SZ126DFT2G is also characterized by its Schmitt trigger action at all inputs, making the circuit tolerant to slower input rise and fall times.

The NL17SZ126DFT2G comes in an ultra-small SC-88A/SOT-353 package, which is designed for space-constrained applications. This compact footprint allows for high-density board layouts, making it an excellent choice for portable and miniaturized electronic devices. The device's 3-state output feature enables the output to assume a high impedance (Hi-Z) state, in addition to the normal logic levels, which is essential for preventing bus contention.

ON Semiconductor has ensured that the NL17SZ126DFT2G meets stringent quality standards, providing reliable performance and durability. This product is also compliant with the RoHS directive, making it an environmentally friendly choice for electronic manufacturers who are committed to reducing the environmental impact of their products.

In summary, the NL17SZ126DFT2G by ON Semiconductor is a versatile and efficient non-inverting buffer with a 3-state output, suitable for a variety of applications requiring low power, high speed, and compact design. Its compatibility with different voltage levels and its robustness against noise make it a preferred choice for designers looking to create reliable and high-performing electronic systems.