Allicdata Part #: | NLVHC1G08DFT2G-ND |
Manufacturer Part#: |
NLVHC1G08DFT2G |
Price: | $ 0.00 |
Product Category: | Integrated Circuits (ICs) |
Manufacturer: | ON Semiconductor |
Short Description: | IC GATE AND 1CH 2-INP SC88A |
More Detail: | AND Gate IC 1 Channel SC-88A (SC-70-5/SOT-353) |
DataSheet: | NLVHC1G08DFT2G Datasheet/PDF |
Quantity: | 1000 |
1 +: | 0.00000 |
Series: | Automotive, AEC-Q100, 74HC |
Packaging: | Tape & Reel (TR) |
Part Status: | Obsolete |
Logic Type: | AND Gate |
Number of Circuits: | 1 |
Number of Inputs: | 2 |
Features: | -- |
Voltage - Supply: | 2 V ~ 6 V |
Current - Quiescent (Max): | 1µA |
Current - Output High, Low: | 2.6mA, 2.6mA |
Logic Level - Low: | 0.5 V ~ 1.8 V |
Logic Level - High: | 1.5 V ~ 4.2 V |
Max Propagation Delay @ V, Max CL: | 17ns @ 6V, 50pF |
Operating Temperature: | -55°C ~ 125°C |
Mounting Type: | Surface Mount |
Supplier Device Package: | SC-88A (SC-70-5/SOT-353) |
Package / Case: | 5-TSSOP, SC-70-5, SOT-353 |
Base Part Number: | 74HC1G08 |
Due to market price fluctuations, if you need to purchase or consult the price. You can contact us or emial to us: sales@allicdata.com
Logic gates and inverters play an important role in the world of modern technology. The capabilities to perform complex but extremely efficient calculations makes them widely relied upon in everyday applications. The NLVHC1G08DFT2G logic gate is a popular choice amongst electrical engineers and hobbyists due to its excellent performance and economical price tag.
NLVHC1G08DFT2G is a power-saving, low voltage-capable, double-gate-level logic device. It is an 8-channel device that is housed in a single 8-pin package. It is designed for 3.3V, 5V and 12V applications, and features low input capacitance for maximum output speed.
The NLVHC1G08DFT2G is a great choice for applications where size, cost and power-saving performance are an issue. It can be used in digital circuits for input switching, signal buffering, voltage level shifting, and for interfacing multiple digital logic families which operate at different voltage levels. It is also suitable for devices that have high switching speed requirements and require a minimum of power consumption.
When it comes to the working principle of NLVHC1G08DFT2G, one must understand the basic logic gates and how they are implemented. Logic gates are a type of digital circuit that is used to perform logical operations on a set of inputs. A single logic gate can contain one or more inputs and one or more outputs. The output of a logic gate is a Boolean logical outcome, either 0 (low) or 1 (high).
Logic gates are constructed using transistors, diodes, or some other type of material depending on the particular logic gate implementation. The majority of logic gates have two types of inputs, including a control or enable input and an active input. The control input is used to enable the gate and is usually active when set high or enabled, while the active input is used to accept the data that is to be operated upon. When the control input is disabled, the active input is disconnected and the output is prevented from producing any logic feedback.
At the heart of NLVHC1G08DFT2G lies a transistor-transistor logic (TTL) circuit. This is a widely used type of digital circuit that is used in many modern applications. TTL circuits consist of transistors paired in a precisely arranged circuit configuration that controls the flow of current based on the input signals. TTL circuit outputs can be either low (0V) or high (3.3V or 5V depending on the power supply used in the application).
The main feature of NLVHC1G08DFT2G is its high speed as well as low power consumption. This makes it perfect for applications that require high speed and low power. It also features adjustable current drive, low input capacitance for maximum output speed, and is housed in an 8-pin package rather than more conventional 14-pin packages.
Inverters are also a type of logic circuit that can be used with the NLVHC1G08DFT2G. An inverter is a logic circuit that takes an input signal and produces an ouput that is the opposite of the input. If the input is 0, the output is 1 and if the input is 1, the output is 0. Inverters are used in electronic circuits and electrical circuits to accomplish logic operations.
Inverters can be implemented using both NAND and NOR gates. NAND gates take two or more inputs and produce an output that is low when all inputs are high and high when any one or more of the inputs are low. NOR gates, on the other hand, take two or more inputs and produce an output that is high when all inputs are low and low when any one or more of the inputs are high. In both cases, the output produced is the opposite of the inputs.
These logic gates and inverters are used in many applications. These can be found in defense systems, robotics, digital logic circuits, computers, cameras, and so on. NLVHC1G08DFT2G logic gates can be used to connect two or more sources, allowing a variety of electrical signals to flow through the circuit. Inverters can be used to control the manner in which the signals are input and interpreted by a variety of microcontrollers. They are also commonly used in digital electronics for signal conditioning and signal isolation.
NLVHC1G08DFT2G logic gates and inverters provide a powerful and affordable solution for those looking for the best in electrical engineering and hobbyist applications. With its compact size and low power consumption, it is an excellent choice for digital circuits, signal buffers, voltage level shifting, and more. They also feature high switching speeds and low input capacitance, ensuring that the circuit will be operation at maximum efficiency. Loss of data will also be minimized due to their ability to detect and prevent signal glitches. All in all, NLVHC1G08DFT2G logic gates and inverters are the perfect choice for any digital engineering project.
The specific data is subject to PDF, and the above content is for reference
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