Allicdata Part #: | H11L1TVM_F132-ND |
Manufacturer Part#: |
H11L1TVM_F132 |
Price: | $ 0.00 |
Product Category: | Isolators |
Manufacturer: | ON Semiconductor |
Short Description: | OPTOISO 4.17KV OPN COLL 6DIP |
More Detail: | Logic Output Optoisolator 1MHz Open Collector 4170... |
DataSheet: | H11L1TVM_F132 Datasheet/PDF |
Quantity: | 1000 |
1 +: | 0.00000 |
Specifications
Data Rate: | 1MHz |
Supplier Device Package: | 6-DIP |
Package / Case: | 6-DIP (0.400", 10.16mm) |
Mounting Type: | Through Hole |
Operating Temperature: | -40°C ~ 85°C |
Voltage - Supply: | 3 V ~ 15 V |
Current - DC Forward (If) (Max): | 30mA |
Voltage - Forward (Vf) (Typ): | 1.2V |
Rise / Fall Time (Typ): | 100ns, 100ns |
Propagation Delay tpLH / tpHL (Max): | 4µs, 4µs |
Series: | -- |
Current - Output / Channel: | 50mA |
Output Type: | Open Collector |
Input Type: | DC |
Common Mode Transient Immunity (Min): | -- |
Voltage - Isolation: | 4170Vrms |
Inputs - Side 1/Side 2: | 1/0 |
Number of Channels: | 1 |
Part Status: | Obsolete |
Packaging: | Tube |
Description
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Optoisolators - Logic Output
The H11L1TVM_F132 optoisolator is a logic output optoisolator, specifically designed to connect various digital logic circuits while isolating them from one another. This type of component provides several important advantages, such as the prevention of noise-induced errors, improved signal accuracy, and improved system reliability. In this article, we’ll discuss the application field and working principle of the H11L1TVM_F132 optoisolator.
Application Field: The H11L1TVM_F132 optoisolator is primarily used in applications in which a digital ground connection must be maintained between two parts of a circuit while noise-induced errors must be prevented. This type of component is ideal for applications such as data transmission systems, field communication networks, industrial automation, and medical systems.
Working Principle: The H11L1TVM_F132 optoisolator works by using an infrared LED that sends an electrical signal through a light-transmitting plastic window. This light is then received by a photodetector, which converts the signal into a voltage signal that can be used by the digital logic circuit. The main advantage of the optoisolator is that it isolates the digital logic circuits from one another, so that any noise-induced errors are not transferred from one circuit to another.
Advantages: The major advantage of the H11L1TVM_F132 optoisolator is the fact that it provides a true level of isolation between digital logic circuits. This type of component prevents any noise-induced errors from being transferred from one circuit to another. Additionally, it ensures that signals are accurately sent and received between two different devices, while also providing improved system reliability.
Disadvantages: The main disadvantage of the H11L1TVM_F132 optoisolator is its cost. As this type of component is quite expensive, they can be difficult to implement in smaller projects or applications. Additionally, this type of component can be difficult to debug, as it requires the user to be familiar with optoisolator-specific diagnostic tools, and the signal waveforms can be difficult to interpret.
In conclusion, the H11L1TVM_F132 optoisolator is a type of logic output optoisolator that is ideal for applications requiring digital ground connection while preventing noise-induced errors. This type of component provides several advantages, such as improved signal accuracy, improved system reliability, and isolation between digital logic circuits. Additionally, it also has some drawbacks, such as high cost and difficulty in debugging.
The H11L1TVM_F132 optoisolator is a logic output optoisolator, specifically designed to connect various digital logic circuits while isolating them from one another. This type of component provides several important advantages, such as the prevention of noise-induced errors, improved signal accuracy, and improved system reliability. In this article, we’ll discuss the application field and working principle of the H11L1TVM_F132 optoisolator.
Application Field: The H11L1TVM_F132 optoisolator is primarily used in applications in which a digital ground connection must be maintained between two parts of a circuit while noise-induced errors must be prevented. This type of component is ideal for applications such as data transmission systems, field communication networks, industrial automation, and medical systems.
Working Principle: The H11L1TVM_F132 optoisolator works by using an infrared LED that sends an electrical signal through a light-transmitting plastic window. This light is then received by a photodetector, which converts the signal into a voltage signal that can be used by the digital logic circuit. The main advantage of the optoisolator is that it isolates the digital logic circuits from one another, so that any noise-induced errors are not transferred from one circuit to another.
Advantages: The major advantage of the H11L1TVM_F132 optoisolator is the fact that it provides a true level of isolation between digital logic circuits. This type of component prevents any noise-induced errors from being transferred from one circuit to another. Additionally, it ensures that signals are accurately sent and received between two different devices, while also providing improved system reliability.
Disadvantages: The main disadvantage of the H11L1TVM_F132 optoisolator is its cost. As this type of component is quite expensive, they can be difficult to implement in smaller projects or applications. Additionally, this type of component can be difficult to debug, as it requires the user to be familiar with optoisolator-specific diagnostic tools, and the signal waveforms can be difficult to interpret.
In conclusion, the H11L1TVM_F132 optoisolator is a type of logic output optoisolator that is ideal for applications requiring digital ground connection while preventing noise-induced errors. This type of component provides several advantages, such as improved signal accuracy, improved system reliability, and isolation between digital logic circuits. Additionally, it also has some drawbacks, such as high cost and difficulty in debugging.
The specific data is subject to PDF, and the above content is for reference
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