SN74AUC16373DGVR Product Introduction:
Texas Instruments Part Number SN74AUC16373DGVR(Logic - Latches), developed and manufactured by Texas Instruments, distributed globally by Jinftry. We distribute various electronic components from world-renowned brands and provide one-stop services, making us a trusted global electronic component distributor.
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Introducing the Texas Instruments SN74AUC16373DGVR, a versatile and high-performance 16-bit transparent D-type latch with 3-state outputs. This innovative product is designed to meet the demanding requirements of modern digital systems, offering exceptional speed and reliability.
The SN74AUC16373DGVR boasts a wide operating voltage range of 0.8V to 3.6V, making it suitable for a variety of applications. With its low power consumption and high-speed operation, this latch is ideal for use in battery-powered devices, portable electronics, and other power-sensitive applications.
Featuring 3-state outputs, the SN74AUC16373DGVR allows for easy interfacing with other devices, enabling efficient data transfer and communication. Its transparent latch design ensures that data is latched and stored accurately, providing reliable and error-free operation.
This latch also offers excellent noise immunity, thanks to its advanced Schmitt-trigger inputs. This feature makes the SN74AUC16373DGVR highly resistant to noise and interference, ensuring reliable operation even in noisy environments.
The SN74AUC16373DGVR is suitable for a wide range of applications, including data storage, address decoding, bus interfacing, and more. Its compact and space-saving package makes it easy to integrate into any design, while its exceptional performance and reliability make it a top choice for engineers and designers.
In summary, the Texas Instruments SN74AUC16373DGVR is a versatile and high-performance 16-bit transparent D-type latch, offering exceptional speed, reliability, and noise immunity. With its wide operating voltage range and low power consumption, it is the perfect choice for a variety of applications in the digital systems industry.
Latches are an important logical storage element in integrated circuits, which are mainly used to temporarily store data or status information in digital circuits until new data or reset signals are received. The locking pin is usually composed of cross-coupled inverter pairs, forming a positive feedback loop to maintain its output state. This design principle allows the locking pin to maintain the stability of the data without the control of the clock signal until the external signal changes its state. The characteristics of the lock pin include its hold function and transparent function, that is, under the control of the enable signal, data can be passed transparently, or in the non-enable state of the latch. These characteristics make locking pins play a key role in digital circuit design, especially in scenarios where transient data or state is required.
Application
Latches play an important role in many application areas of integrated circuits. In the microprocessor, digital signal processor (DSP), field programmable gate array (FPGA) and other high-performance computing and logic control chips, the locking pin is widely used in registers, registers, triggers and other key components to achieve temporary data storage and state management. In addition, in the communication system, the locking pin is also often used in the circuit design of key links such as data synchronization and clock recovery to ensure the accuracy and stability of data transmission. In consumer electronics, automotive electronics, industrial automation and other fields, locking pins are also indispensable, they support the realization of a variety of complex functions, such as audio and video processing, sensor data reading, motor control and so on. In short, as a basic component in digital circuits, the locking pin has a wide range of applications, which is of great significance to improve the performance and stability of the system.
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