Allicdata Part #: | 74LCX543MSA-ND |
Manufacturer Part#: |
74LCX543MSA |
Price: | $ 0.00 |
Product Category: | Integrated Circuits (ICs) |
Manufacturer: | ON Semiconductor |
Short Description: | IC TXRX NON-INVERT 3.6V 24SSOP |
More Detail: | Transceiver, Non-Inverting 1 Element 8 Bit per Ele... |
DataSheet: | 74LCX543MSA Datasheet/PDF |
Quantity: | 1000 |
1 +: | 0.00000 |
Series: | 74LCX |
Packaging: | Tube |
Part Status: | Obsolete |
Logic Type: | Transceiver, Non-Inverting |
Number of Elements: | 1 |
Number of Bits per Element: | 8 |
Input Type: | -- |
Output Type: | 3-State |
Current - Output High, Low: | 24mA, 24mA |
Voltage - Supply: | 2 V ~ 3.6 V |
Operating Temperature: | -40°C ~ 85°C (TA) |
Mounting Type: | Surface Mount |
Package / Case: | 24-SSOP (0.209", 5.30mm Width) |
Supplier Device Package: | 24-SSOP |
Base Part Number: | 74LCX543 |
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As technology continues to progress, the need to quickly and easily process and control multiple signals across integrated circuits and other devices has become increasingly important. The 74LCX543MSA is part of the family of logic-based buffers and transceivers, and it is able to provide users with the necessary performance, features and flexibility that are needed in many mission-critical applications. In this article, we will explain the application field and working principle of the 74LCX543MSA.
Background Information
The 74LCX543MSA is an 8-bit advanced transceiver logic family. It is designed specifically to improve both system performance and signal integrity. The 74LCX543MSA includes both transceiver, receiver and buffer functionality, utilizing dual-supply voltage for both a high and a low voltage supply. It also has adjustable voltage ranges, allowing greater flexibility for users.
At the heart of the 74LCX543MSA is the advanced double-clocking design. This is a unique feature that ensures that data is not lost or corrupted during signal transition due to signal delays. The double-clocking design also ensures that signal flow is properly balanced and synchronized, helping to improve performance and signal integrity.
Applications of 74LCX543MSA
The 74LCX543MSA has a wide range of applications due to its high level of performance, flexibility, and signal integrity. It is often used in mission-critical applications such as high-speed communication systems, computer buses, clock distribution circuits, and controlling high-speed peripherals. It is also used in the communication industry, where its dual-clocking design is beneficial in ensuring that signals remain in synchronization with one another.
The 74LCX543MSA can also be used for a wide range of consumer goods, such as television sets, audio equipment, and automobiles. It is also used in both industrial robots and other similar control systems. The applications of the 74LCX543MSA are almost endless, with its advanced performance and flexibility being highly valuable in many modern-day applications.
Working Principle of 74LCX543MSA
The primary function of the 74LCX543MSA is to facilitate the transfer of digital signals from one circuit to another. This is done by using a pair of synchronized clock signals, which are driven by the dual-voltage power supply system of the device. The clock signals drive the appropriate transceiver elements of the 74LCX543MSA to enable it to buffer and receive signals from both its inputs and outputs.
The first stage of the signal flow process is the input buffers. The input stage includes three inputs (A, B, and OE) that are used to control the flow of the signal. The A and B inputs are used to select the appropriate channels for the signal to flow through, while the OE input is used to enable or disable the channel select latch. When the OE input is enabled, the channel select latch will determine which channel the signal will flow through.
The second stage of the signal flow is the output stage. The output stage consists of three outputs, (A, B, and OE), which can be used to drive output signals to the appropriate destination. The A and B outputs will drive the selected channel, while the OE output will enable and disable the channel select latch. Additionally, the 74LCX543MSA has an output enable input that can be used to further control the flow of the signals.
Finally, the double-clocking system ensures that the signals remain in synchronization with each other. This is achieved by using two separate and independent clock signals, which are used to control both the input and output stages. With this double-clocking system, the 74LCX543MSA is able to provide unparalleled performance and signal integrity.
Conclusion
The 74LCX543MSA is an advanced logic family that is designed to provide users with a high level of performance, flexibility, and signal integrity. It is highly versatile and is used in a wide variety of mission-critical applications. The double-clocking design of the 74LCX543MSA allows it to maintain a high level of signal synchronization, ensuring that data is not corrupted during signal transition. By utilizing this advanced transceiver logic family, users can benefit from a reliable and efficient signal transceiver system, making the 74LCX543MSA an all-around excellent choice for mission-critical applications.
The specific data is subject to PDF, and the above content is for reference
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