Allicdata Part #: | H11N3-ND |
Manufacturer Part#: |
H11N3 |
Price: | $ 0.00 |
Product Category: | Isolators |
Manufacturer: | ON Semiconductor |
Short Description: | OPTOCOUPLER SCMITT TRIGGER OUT |
More Detail: | Logic Output Optoisolator 5MHz Open Collector 7500... |
DataSheet: | H11N3 Datasheet/PDF |
Quantity: | 1000 |
Series: | -- |
Packaging: | Tube |
Part Status: | Obsolete |
Number of Channels: | 1 |
Inputs - Side 1/Side 2: | 1/0 |
Voltage - Isolation: | 7500Vrms |
Common Mode Transient Immunity (Min): | -- |
Input Type: | DC |
Output Type: | Open Collector |
Current - Output / Channel: | 50mA |
Data Rate: | 5MHz |
Propagation Delay tpLH / tpHL (Max): | 330ns, 330ns |
Rise / Fall Time (Typ): | -- |
Voltage - Forward (Vf) (Typ): | 1.4V |
Current - DC Forward (If) (Max): | 10mA |
Voltage - Supply: | -- |
Operating Temperature: | -- |
Mounting Type: | Through Hole |
Package / Case: | 6-DIP (0.300", 7.62mm) |
Supplier Device Package: | 6-DIP |
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.Optoisolators - Logic Output
Optoisolators, also known as optocouplers, are devices designed to transfer electrical signals between separated circuits in order to reduce electrical noise and to protect devices from electrical damage caused by over-voltage or static electricity. H11N3 is an optoisolator type designed for logic output. It offers a wide range of input signals, high-speed data rates, and many different circuits, making it suitable for a variety of applications. This article will discuss the applications and working principles of the H11N3 optoisolator.
Applications
The H11N3 optoisolator can be used in a variety of applications, including industrial control systems, automotive electronics, and consumer electronics. It is also well-suited for military and aerospace applications due to its isolation feature which helps to protect sensitive circuits from damage caused by loud noises, high voltage, and other extreme environmental conditions. Additionally, the H11N3 offers fast switching speeds which make it ideal for high-speed data transmission in communication systems.
The optoisolator is also widely used in medical device applications, such as infusion pumps and glucose meters. Its isolation feature helps to protect the medical device from static electricity and other electrical interference. Furthermore, the device’s high-speed switching speeds make it ideal for controlling the flow of various liquids and measuring the electrical output of medical sensors.
Working Principle
The working principle of the H11N3 optoisolator is based on the transfer of electrical signals across an optically isolated gap. It consists of two elements, an input element and an output element, connected by an optical link. The input element typically consists of a LED, or a photo-diode, and the output element usually includes a photo-transistor or a photo-resistant device. The LED produces light when an electrical current passes through it, which is then detected by the output element, triggering the current in the output element.
In order for the transfer of electrical signals to occur across the optical gap, the LED must be triggered by an external control circuit. This can be achieved either directly or indirectly by using a logic element such as a comparator or an amplifier. The input logic voltage is then converted into an optical signal by the LED, which is then transferred to the output element. The output element then converts the optical signal back into an electrical one, which can be used to control the current flow within the device. The output logic voltage is thus equal to the input logic voltage.
Conclusion
The H11N3 optoisolator is a popular and versatile optoisolator type designed for logic output. It offers high-speed data transmission, fast switching speeds, and a wide variety of input signals, making it suitable for use in a variety of applications, such as industrial control systems, automotive electronics, medical device applications, and consumer electronics. In addition, its isolation feature helps to protect sensitive circuits from noise and electrical damage. The working principle of the H11N3 optoisolator is based on the electrical transfer of signals across an optically isolated gap, and is achieved by a logic element such as a comparator or an amplifier.
The specific data is subject to PDF, and the above content is for reference
Part Number | Manufacturer | Price | Quantity | Description |
---|
H11N1 | ON Semicondu... | -- | 1000 | OPTOCOUPLER SCMITT TRIGGE... |
H11N3 | ON Semicondu... | -- | 1000 | OPTOCOUPLER SCMITT TRIGGE... |
H11N3-M | ON Semicondu... | 0.0 $ | 1000 | OPTOCOUPLER SCHMITT-TRIG ... |
H11N1300 | ON Semicondu... | 0.0 $ | 1000 | OPTOCOUP VDE SCHM TRIG OU... |
H11N1300W | ON Semicondu... | 0.0 $ | 1000 | OPTOCOUP VDE WIDE SCHM TR... |
H11N13S | ON Semicondu... | 0.0 $ | 1000 | OPTOCOUP VDE SCHM TRIG OU... |
H11N13SD | ON Semicondu... | 0.0 $ | 1000 | OPTOCOUP VDE SCHM TRIG OU... |
H11N1S | ON Semicondu... | 0.0 $ | 1000 | OPTOCOUPLER SCHMITT TRIG ... |
H11N1SD | ON Semicondu... | 0.0 $ | 1000 | OPTOCOUPLER SCHMITT TRIG ... |
H11N1W | ON Semicondu... | 0.0 $ | 1000 | OPTOCOUP WIDE SCHM TRIG O... |
H11N2 | ON Semicondu... | -- | 1000 | OPTOCOUPLER SCHMIT TRIG O... |
H11N2300 | ON Semicondu... | 0.0 $ | 1000 | OPTOCOUP VDE SCHM TRIG OU... |
H11N2300W | ON Semicondu... | 0.0 $ | 1000 | OPTOCOUP VDE WIDE SCHM TR... |
H11N23S | ON Semicondu... | 0.0 $ | 1000 | OPTOCOUP VDE SCHM TRIG OU... |
H11N23SD | ON Semicondu... | 0.0 $ | 1000 | OPTOCOUP VDE SCHM TRIG OU... |
H11N2S | ON Semicondu... | 0.0 $ | 1000 | OPTOCOUPLER SCHMITT TRIG ... |
H11N2SD | ON Semicondu... | 0.0 $ | 1000 | OPTOCOUPLER SCHMITT TRIG ... |
H11N2W | ON Semicondu... | 0.0 $ | 1000 | OPTOCOUP WIDE SCHM TRIG O... |
H11N3300 | ON Semicondu... | 0.0 $ | 1000 | OPTOCOUP VDE SCHM TRIG OU... |
H11N3300W | ON Semicondu... | 0.0 $ | 1000 | OPTOCOUP VDE WIDE SCHM TR... |
H11N33S | ON Semicondu... | 0.0 $ | 1000 | OPTOCOUP VDE SCHMIT TRIG ... |
H11N33SD | ON Semicondu... | 0.0 $ | 1000 | OPTOCOUP VDE SCHMIT TRIG ... |
H11N3S | ON Semicondu... | 0.0 $ | 1000 | OPTOCOUPLER SCHMITT TRIG ... |
H11N3SD | ON Semicondu... | 0.0 $ | 1000 | OPTOCOUPLER SCHMITT TRIG ... |
H11N3W | ON Semicondu... | 0.0 $ | 1000 | OPTOCOUP WIDE SCHM TRIG O... |
H11N3FR2VM | ON Semicondu... | 0.0 $ | 1000 | OPTOISO 4.17KV OPN COLL 6... |
H11N3SVM | ON Semicondu... | 0.0 $ | 1000 | OPTOISO 4.17KV OPN COLL 6... |
H11N3FM | ON Semicondu... | 0.0 $ | 1000 | OPTOISO 4.17KV OPN COLL 6... |
H11N3FVM | ON Semicondu... | 0.0 $ | 1000 | OPTOISO 4.17KV OPN COLL 6... |
H11N3SM | ON Semicondu... | 0.0 $ | 1000 | OPTOISO 4.17KV OPN COLL 6... |
H11N3SR2VM | ON Semicondu... | 0.0 $ | 1000 | OPTOISO 4.17KV OPN COLL 6... |
H11N3TVM | ON Semicondu... | 0.0 $ | 1000 | OPTOISO 4.17KV OPN COLL 6... |
H11N3FR2M | ON Semicondu... | 0.0 $ | 1000 | OPTOISO 4.17KV OPN COLL 6... |
H11N3SR2M | ON Semicondu... | 0.0 $ | 1000 | OPTOISO 4.17KV OPN COLL 6... |
H11N3VM | ON Semicondu... | 0.0 $ | 1000 | OPTOISO 4.17KV OPN COLL 6... |
H11N3TM | ON Semicondu... | 0.0 $ | 1000 | OPTOISO 4.17KV OPN COLL 6... |
H11N2VM | ON Semicondu... | 0.0 $ | 1000 | OPTOISO 4.17KV OPN COLL 6... |
H11N2FVM | ON Semicondu... | 0.0 $ | 1000 | OPTOISO 4.17KV OPN COLL 6... |
H11N2TVM | ON Semicondu... | 0.0 $ | 1000 | OPTOISO 4.17KV OPN COLL 6... |
H11N2SVM | ON Semicondu... | 0.0 $ | 1000 | OPTOISO 4.17KV OPN COLL 6... |
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