4N36 Optocoupler: Datasheet, Pinout, 4N35 vs.4N36 vs.4N37

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Published: 25 October 2021 | Last Updated: 25 October 2021

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4N36

4N36

Vishay Semiconductor Opto Division

VISHAY - 4N36 - OPTOCOUPLER, PHOTOTRANSISTOR, 5000VRMS

Purchase Guide

VISHAY - 4N36 - OPTOCOUPLER, PHOTOTRANSISTOR, 5000VRMS

This post will unlock more details about 4N36, an optocoupler made for general purpose applications. There is a huge range of Semiconductors, Capacitors, Resistors and ICs in stock. Welcome RFQ.

This video is about 4N36.

The 4N36

4N36 Pinout

4N36 Pinout.jpg

4N36 Pinout

4N36 Pin Description.jpg

4N36 Pin Description

4N36 Description

The 4N36 optocoupler is a general-purpose optocoupler. It comes in a 6 pin dip package as well as SMD packaging. It has two internal components, one of which is an IR LED and the other is a phototransistor. The 4N36 optocoupler functions in the same way as any other comparable optocoupler.


Specifications

Vishay Semiconductor Opto Division 4N36 technical specifications, attributes, parameters and parts with similar specifications to Vishay Semiconductor Opto Division 4N36.
  • Type
    Parameter
  • Factory Lead Time
    14 Weeks
  • Mount

    In electronic components, the term "Mount" typically refers to the method or process of physically attaching or fixing a component onto a circuit board or other electronic device. This can involve soldering, adhesive bonding, or other techniques to secure the component in place. The mounting process is crucial for ensuring proper electrical connections and mechanical stability within the electronic system. Different components may have specific mounting requirements based on their size, shape, and function, and manufacturers provide guidelines for proper mounting procedures to ensure optimal performance and reliability of the electronic device.

    PCB, Through Hole
  • Mounting Type

    The "Mounting Type" in electronic components refers to the method used to attach or connect a component to a circuit board or other substrate, such as through-hole, surface-mount, or panel mount.

    Through Hole
  • Package / Case

    refers to the protective housing that encases an electronic component, providing mechanical support, electrical connections, and thermal management.

    6-DIP (0.300, 7.62mm)
  • Number of Pins
    6
  • Supplier Device Package

    The parameter "Supplier Device Package" in electronic components refers to the physical packaging or housing of the component as provided by the supplier. It specifies the form factor, dimensions, and layout of the component, which are crucial for compatibility and integration into electronic circuits and systems. The supplier device package information typically includes details such as the package type (e.g., DIP, SOP, QFN), number of pins, pitch, and overall size, allowing engineers and designers to select the appropriate component for their specific application requirements. Understanding the supplier device package is essential for proper component selection, placement, and soldering during the manufacturing process to ensure optimal performance and reliability of the electronic system.

    6-DIP
  • Collector-Emitter Breakdown Voltage
    30V
  • Collector-Emitter Saturation Voltage
    300mV
  • Current Transfer Ratio-Min
    100% @ 10mA
  • Number of Elements
    1
  • Operating Temperature

    The operating temperature is the range of ambient temperature within which a power supply, or any other electrical equipment, operate in. This ranges from a minimum operating temperature, to a peak or maximum operating temperature, outside which, the power supply may fail.

    -55°C~100°C
  • Packaging

    Semiconductor package is a carrier / shell used to contain and cover one or more semiconductor components or integrated circuits. The material of the shell can be metal, plastic, glass or ceramic.

    Tube
  • Published
    2014
  • Part Status

    Parts can have many statuses as they progress through the configuration, analysis, review, and approval stages.

    Active
  • Moisture Sensitivity Level (MSL)

    Moisture Sensitivity Level (MSL) is a standardized rating that indicates the susceptibility of electronic components, particularly semiconductors, to moisture-induced damage during storage and the soldering process, defining the allowable exposure time to ambient conditions before they require special handling or baking to prevent failures

    1 (Unlimited)
  • Max Operating Temperature

    The Maximum Operating Temperature is the maximum body temperature at which the thermistor is designed to operate for extended periods of time with acceptable stability of its electrical characteristics.

    100°C
  • Min Operating Temperature

    The "Min Operating Temperature" parameter in electronic components refers to the lowest temperature at which the component is designed to operate effectively and reliably. This parameter is crucial for ensuring the proper functioning and longevity of the component, as operating below this temperature may lead to performance issues or even damage. Manufacturers specify the minimum operating temperature to provide guidance to users on the environmental conditions in which the component can safely operate. It is important to adhere to this parameter to prevent malfunctions and ensure the overall reliability of the electronic system.

    -55°C
  • Voltage - Rated DC

    Voltage - Rated DC is a parameter that specifies the maximum direct current (DC) voltage that an electronic component can safely handle without being damaged. This rating is crucial for ensuring the proper functioning and longevity of the component in a circuit. Exceeding the rated DC voltage can lead to overheating, breakdown, or even permanent damage to the component. It is important to carefully consider this parameter when designing or selecting components for a circuit to prevent any potential issues related to voltage overload.

    1.3V
  • Max Power Dissipation

    The maximum power that the MOSFET can dissipate continuously under the specified thermal conditions.

    70mW
  • Base Part Number

    The "Base Part Number" (BPN) in electronic components serves a similar purpose to the "Base Product Number." It refers to the primary identifier for a component that captures the essential characteristics shared by a group of similar components. The BPN provides a fundamental way to reference a family or series of components without specifying all the variations and specific details.

    4N36
  • Approval Agency

    The parameter "Approval Agency" in electronic components refers to the organization responsible for testing and certifying that a component meets specific safety, quality, and performance standards. These agencies evaluate products to ensure compliance with industry regulations and standards, providing assurance to manufacturers and consumers. Approval from recognized agencies can enhance a component's marketability and acceptance in various applications, particularly in sectors like automotive, aerospace, and healthcare. Common approval agencies include Underwriters Laboratories (UL), International Electrotechnical Commission (IEC), and the American National Standards Institute (ANSI).

    BSI, FIMKO, UL
  • Voltage - Isolation

    Voltage - Isolation is a parameter in electronic components that refers to the maximum voltage that can be safely applied between two isolated points without causing electrical breakdown or leakage. It is a crucial specification for components such as transformers, optocouplers, and capacitors that require isolation to prevent electrical interference or safety hazards. The voltage isolation rating ensures that the component can withstand the specified voltage without compromising its performance or safety. It is typically measured in volts and is an important consideration when designing circuits that require isolation between different parts of the system.

    5000Vrms
  • Output Voltage

    Output voltage is a crucial parameter in electronic components that refers to the voltage level produced by the component as a result of its operation. It represents the electrical potential difference between the output terminal of the component and a reference point, typically ground. The output voltage is a key factor in determining the performance and functionality of the component, as it dictates the level of voltage that will be delivered to the connected circuit or load. It is often specified in datasheets and technical specifications to ensure compatibility and proper functioning within a given system.

    30V
  • Output Type

    The "Output Type" parameter in electronic components refers to the type of signal or data that is produced by the component as an output. This parameter specifies the nature of the output signal, such as analog or digital, and can also include details about the voltage levels, current levels, frequency, and other characteristics of the output signal. Understanding the output type of a component is crucial for ensuring compatibility with other components in a circuit or system, as well as for determining how the output signal can be utilized or processed further. In summary, the output type parameter provides essential information about the nature of the signal that is generated by the electronic component as its output.

    Transistor with Base
  • Number of Channels
    1
  • Voltage

    Voltage is a measure of the electric potential difference between two points in an electrical circuit. It is typically represented by the symbol "V" and is measured in volts. Voltage is a crucial parameter in electronic components as it determines the flow of electric current through a circuit. It is responsible for driving the movement of electrons from one point to another, providing the energy needed for electronic devices to function properly. In summary, voltage is a fundamental concept in electronics that plays a key role in the operation and performance of electronic components.

    6V
  • Power Dissipation

    the process by which an electronic or electrical device produces heat (energy loss or waste) as an undesirable derivative of its primary action.

    70mW
  • Voltage - Forward (Vf) (Typ)

    The parameter "Voltage - Forward (Vf) (Typ)" in electronic components refers to the typical forward voltage drop across the component when it is conducting current in the forward direction. It is a crucial characteristic of components like diodes and LEDs, indicating the minimum voltage required for the component to start conducting current. The forward voltage drop is typically specified as a typical value because it can vary slightly based on factors such as temperature and manufacturing tolerances. Designers use this parameter to ensure that the component operates within its specified voltage range and to calculate power dissipation in the component.

    1.3V
  • Input Type

    Input type in electronic components refers to the classification of the signal or data that a component can accept for processing or conversion. It indicates whether the input is analog, digital, or a specific format such as TTL or CMOS. Understanding input type is crucial for ensuring compatibility between different electronic devices and circuits, as it determines how signals are interpreted and interacted with.

    DC
  • Forward Current

    Current which flows upon application of forward voltage.

    50mA
  • Max Output Voltage

    The maximum output voltage refers to the dynamic area beyond which the output is saturated in the positive or negative direction, and is limited according to the load resistance value.

    30V
  • Output Current per Channel

    Output Current per Channel is a specification commonly found in electronic components such as amplifiers, audio interfaces, and power supplies. It refers to the maximum amount of electrical current that can be delivered by each individual output channel of the component. This parameter is important because it determines the capacity of the component to drive connected devices or loads. A higher output current per channel means the component can deliver more power to connected devices, while a lower output current may limit the performance or functionality of the component in certain applications. It is crucial to consider the output current per channel when selecting electronic components to ensure they can meet the power requirements of the intended system or setup.

    50mA
  • Rise Time

    In electronics, when describing a voltage or current step function, rise time is the time taken by a signal to change from a specified low value to a specified high value.

    2μs
  • Forward Voltage

    the amount of voltage needed to get current to flow across a diode.

    1.3V
  • Fall Time (Typ)

    Fall Time (Typ) is a parameter used to describe the time it takes for a signal to transition from a high level to a low level in an electronic component, such as a transistor or an integrated circuit. It is typically measured in nanoseconds or microseconds and is an important characteristic that affects the performance of the component in digital circuits. A shorter fall time indicates faster switching speeds and can result in improved overall circuit performance, such as reduced power consumption and increased data transmission rates. Designers often consider the fall time specification when selecting components for their circuits to ensure proper functionality and efficiency.

    2 μs
  • Collector Emitter Voltage (VCEO)

    Collector-Emitter Voltage (VCEO) is a key parameter in electronic components, particularly in transistors. It refers to the maximum voltage that can be applied between the collector and emitter terminals of a transistor while the base terminal is open or not conducting. Exceeding this voltage limit can lead to breakdown and potential damage to the transistor. VCEO is crucial for ensuring the safe and reliable operation of the transistor within its specified limits. Designers must carefully consider VCEO when selecting transistors for a circuit to prevent overvoltage conditions that could compromise the performance and longevity of the component.

    30V
  • Max Collector Current

    Max Collector Current is a parameter used to specify the maximum amount of current that can safely flow through the collector terminal of a transistor or other electronic component without causing damage. It is typically expressed in units of amperes (A) and is an important consideration when designing circuits to ensure that the component operates within its safe operating limits. Exceeding the specified max collector current can lead to overheating, degradation of performance, or even permanent damage to the component. Designers must carefully consider this parameter when selecting components and designing circuits to ensure reliable and safe operation.

    100mA
  • Reverse Breakdown Voltage

    Reverse Breakdown Voltage is the maximum reverse voltage a semiconductor device can withstand before it starts to conduct heavily in the reverse direction. It is a critical parameter in diodes and other components, indicating the threshold at which the material's insulating properties fail. Beyond this voltage, the device may enter a breakdown region, leading to potential damage if not properly managed. This parameter is essential for ensuring safe operation and reliability in electronic circuits.

    6V
  • Max Input Current

    Max Input Current is a parameter that specifies the maximum amount of electrical current that can safely flow into an electronic component without causing damage. It is an important consideration when designing or using electronic circuits to ensure that the component operates within its specified limits. Exceeding the maximum input current can lead to overheating, component failure, or even pose safety risks. Manufacturers provide this parameter in datasheets to help engineers and users understand the limitations of the component and ensure proper operation within the specified parameters.

    50mA
  • Current - DC Forward (If) (Max)

    The parameter "Current - DC Forward (If) (Max)" in electronic components refers to the maximum forward current that can safely pass through the component without causing damage. This parameter is typically specified in datasheets for diodes and LEDs, indicating the maximum current that can flow through the component in the forward direction. Exceeding this maximum current rating can lead to overheating and potentially permanent damage to the component. It is important to ensure that the current flowing through the component does not exceed this specified maximum to maintain proper functionality and reliability.

    50mA
  • Input Current

    Input current is a parameter that refers to the amount of electrical current flowing into a specific electronic component or device. It is typically measured in amperes (A) and represents the current required for the component to operate properly. Understanding the input current is important for designing circuits and power supplies, as it helps determine the capacity and compatibility of the components being used. Monitoring the input current also helps ensure that the component is not being overloaded or underpowered, which can affect its performance and longevity.

    10mA
  • Turn On / Turn Off Time (Typ)

    Turn On / Turn Off Time (Typ) in electronic components refers to the time it takes for a device to switch from a non-conducting state to a conducting state (Turn On) and vice versa (Turn Off). This parameter is crucial for understanding the speed and responsiveness of the component in switching applications. It typically indicates the average time under specified conditions and is essential for optimizing the performance in circuits where rapid switching is required, such as in power electronics and digital logic devices.

    10μs, 10μs
  • Current Transfer Ratio

    Current Transfer Ratio (CTR) is the gain of the optocoupler. It is the ratio of the phototransistor collector current to the IRED forward current. CTR = (IC / IF) * 100 It is expressed as a percentage (%).

    50 %
  • Height
    4mm
  • Length
    7.62mm
  • Width
    7mm
  • REACH SVHC

    The parameter "REACH SVHC" in electronic components refers to the compliance with the Registration, Evaluation, Authorization, and Restriction of Chemicals (REACH) regulation regarding Substances of Very High Concern (SVHC). SVHCs are substances that may have serious effects on human health or the environment, and their use is regulated under REACH to ensure their safe handling and minimize their impact.Manufacturers of electronic components need to declare if their products contain any SVHCs above a certain threshold concentration and provide information on the safe use of these substances. This information allows customers to make informed decisions about the potential risks associated with using the components and take appropriate measures to mitigate any hazards.Ensuring compliance with REACH SVHC requirements is essential for electronics manufacturers to meet regulatory standards, protect human health and the environment, and maintain transparency in their supply chain. It also demonstrates a commitment to sustainability and responsible manufacturing practices in the electronics industry.

    Unknown
  • Radiation Hardening

    Radiation hardening is the process of making electronic components and circuits resistant to damage or malfunction caused by high levels of ionizing radiation, especially for environments in outer space (especially beyond the low Earth orbit), around nuclear reactors and particle accelerators, or during nuclear accidents or nuclear warfare.

    No
  • RoHS Status

    RoHS means “Restriction of Certain Hazardous Substances” in the “Hazardous Substances Directive” in electrical and electronic equipment.

    ROHS3 Compliant
  • Lead Free

    Lead Free is a term used to describe electronic components that do not contain lead as part of their composition. Lead is a toxic material that can have harmful effects on human health and the environment, so the electronics industry has been moving towards lead-free components to reduce these risks. Lead-free components are typically made using alternative materials such as silver, copper, and tin. Manufacturers must comply with regulations such as the Restriction of Hazardous Substances (RoHS) directive to ensure that their products are lead-free and environmentally friendly.

    Lead Free
0 Similar Products Remaining

Parts with Similar Specs

The three parts on the right have similar specifications to Vishay Semiconductor Opto Division & 4N36.
  • Image
    Part Number
    Manufacturer
    Package / Case
    Number of Pins
    Number of Channels
    Voltage - Isolation
    Current Transfer Ratio
    Current Transfer Ratio (Min)
    Rise Time
    Max Output Voltage
    Output Voltage
    Forward Voltage
    View Compare
  • 4N36

    4N36

    6-DIP (0.300, 7.62mm)

    6

    1

    5000Vrms

    50 %

    100% @ 10mA

    2 μs

    30 V

    30 V

    1.3 V

4N36 Feature

• Isolation test voltage 5000 VRMS

• Interfaces with common logic families

• Input-output coupling capacitance < 0.5 pF

• Industry-standard dual-in-line 6 pin package

• Compliant to RoHS directive 2002/95/EC and in accordance to WEEE 2002/96/EC


4N36 Application

AC mains detection

Reed relay driving

Switch mode power supply feedback

Telephone ring detection

Logic ground isolation

Logic coupling with high frequency noise rejection


4N36 Replacement

The replacement for 4N36:

  • 4N35

  • 4N37

  • 4N25

  • 4N26

  • 4N28

  • PC816

  • PC817 

  • 4N27

  • 4N36

  • H11Ax series.


Where to use 4N36

The 4N36 optocoupler can be used in a variety of applications, including protecting circuits from voltage spikes, creating isolation between two circuits, and detecting the presence of AC or DC current. It can also be utilized at the output of microcontrollers and other ICs with low output current so that high-current components, such as high-power transistors, can be operated with these ICs and microcontrollers.


How to use 4N36

It's as simple as using a regular LED and a phototransistor to use a 4N36 optocoupler. Connect the anode of the IR LED to the positive output of your component, which can be an IC or microcontroller, and the other pin (Cathode) to the negative or ground of that component to use the device. It is critical to use a current limiting resistor between the output of the IC or microcontroller and the anode of the IR LED.

When the phototransistor detects light from the IR LED, the collector and emitter pins will link, and anything connected to pins 4 and 5 will become connected as well. As previously stated, the phototransistor can be controlled by its other base, which is connected to pin 6, allowing the user to operate the transistor via its other base / pin6.


4N36 Package

4N36 Package.jpg

4N36 Package

4N36 Manufacturer

Vishay, an important partner of Digi-Key, serves as a globally recognized manufacturer famous for its discrete semiconductors and passive electronic components. Their discrete semiconductors include diodes, MOSFETs, optoelectronics, etc and their passive components include resistors, inductors, capacitors, etc. These products are widely used for almost all kinds of electronic devices and equipment in the fields of industrial, computing, automotive, telecommunications, military, aerospace, and medical.

Datasheet PDF

Download datasheets and manufacturer documentation for Vishay Semiconductor Opto Division 4N36.

Popularity by Region

Datasheet PDF

Download datasheets and manufacturer documentation for Vishay Semiconductor Opto Division 4N36.

Popularity by Region

Frequently Asked Questions

What does 4N36 do?

The 4N36 is an optocoupler for general purpose application. It consists of gallium arsenide infrared LED and a silicon NPN phototransistor. What an optocoupler does is to break the connection between the signal source and signal receiver, so as to stop electrical interference.

How does 4N36 operate in safety?

If you want to get the best long-term performance out of your 4N36, make sure you use it at its maximum specs. Always connect a load that draws less than 150 mA. With the IR LED / on pin 1, use a current limiting resistor. Never use the device in temperatures below -55 degrees Fahrenheit and over +100 degrees Fahrenheit, and never store it in temperatures below -55 degrees Fahrenheit and above +150 degrees Fahrenheit.

What is an optocoupler used for?

Optocouplers can either be used on their own as a switching device or used with other electronic devices to provide isolation between low and high voltage circuits. You'll typically find these devices being used for Microprocessor input/output switching. DC and AC power control.
4N36

Vishay Semiconductor Opto Division

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