1N5820 Schottky Diode Pinout, Specifications and Datasheet

Hi Friends! Happy to see you around. I welcome you on board. In this post today, I’ll discuss the Introduction to 1n5820.

The 1n5820 is a Schottky diode, also known as a hot-carrier diode, capable of extremely fast switching and is well protected against overvoltage. It carries a low forward voltage drop and high forward surge capability. It is capable of high-frequency operation and comes in the DO-201AD package. When less power dissipation is required, MOSFETs can be used in place of Schottky diodes. Just stay with me for a little while as I’ll walk you through the datasheet, pinout, features, and applications of this device 1n5820. Let’s jump right in.

Introduction to 1N5820

  • 1n5820 is a Schottky diode composed of semiconductor material and is employed in fast-clamp diode switching applications.
  • Schottky diode is also called hot-carrier diode since in an unbiased condition electrons possess low energy on the semiconductor material.
  • This low energy leads to the formation of a barrier that blocks the electrons. Due to the formation of this barrier, Schottky diodes are also called hot-carrier diodes.
  • Both Schottky diode and normal diode are different in terms of voltage required to power up these diodes.
  • The Schottky diode requires only 0.3V out of 2V DC source voltage, leaving 1.7V to power the diode. On the other hand, a normal diode requires only 0.7V, leaving behind 1.3V to power the diode.

1N5820 Datasheet

Before you use this device in your project, it’s always wise to have a look at the datasheet of the device that highlights the main characteristics of the component. Click the link below and download the datasheet of 1n5820.

1N5820 Features

  • Highly efficient with small conduction losses.
  • Protection against overvoltage.
  • Carries low forward drop voltage.
  • Capable of extremely fast switching.
  • Carries high surge capability.
  • Comes in package DO-201AD.

1n5820 Schottky Diode Construction

  • The 1n5820 Schottky diode is formed when metal is combined with the semiconductor material that results in the formation of a barrier.
  • When the n-type semiconductor is combined with metals like platinum, chromium, tungsten, and molybdenum, they make Schottky diode.
  • Both p-type and n-type semiconductor material can be used to construct the Schottky diode, but n-type semiconductors are preferred over p-type semiconductor material because later exhibit low forward drop voltage.
  • The Schottky diode comes with two terminals where one is an anode and the other is called a cathode terminal. The anode, made-up of metal, is always the positive side of the diode through which current enters the diode. And the cathode side, made-up of silicon material, is always the negative side through which current leaves the diode.
  • The conduction is carried out between these two terminals and current flows from the anode terminal to the cathode terminal.
  • The nature of semiconductor material and the metal used plays a key role in defining the forward drop voltage of the diode. Low forward drop voltage means less energy is released as heat that makes these diodes suitable for the applications where high efficiency is required.
  • These diodes are widely used in the solar systems that prevent the batteries from discharging in the absence of solar heat.

1N5820 Pinout

The following figure represents the pinout image of 1n5820.
  • 1n5820 is composed of two terminals mainly used for the external connection with the circuit.
  • These terminals are called the anode side from where the current enters the diode and the cathode side from where the current leaves the diode.
  • The anode side is positive, made up of metal and the cathode side is negative, made-up of silicon material. The current flows from the anode terminal to the cathode terminal.

1N5820 Applications

  • Employed in high-frequency and low voltage inverters.
  • Used in sample-and-hold circuits.
  • Can control the electronic charge.
  • Used in DC/DC converters and polarity protection applications.
  • Incorporated in freewheeling and logic circuits.
  • Used for signal detection and radio frequency applications.
  • Employed in extremely fast switching applications.
  • Used in stand-alone photovoltaic systems.
That’s all for today. I hope you find this article useful. If you’re unsure or have any question, you can approach me in the comment section below, I’ll help you the best way I can. Feel free to keep us updated with your valuable feedback and suggestions, they help us create quality content customized to your exact requirements. Thank you for reading the article.

1N5408 Power Diode Pinout, Datasheet, Features & Equivalents

Hello Friends! Hope you’re well today. I welcome you on board. In this post today, I’ll be discussing the Introduction to 1n5408. The 1n5408 is a component where current flows in one direction only. It comes with two pins named anode and cathode. The Anode side is positive from where the current enters the diode and the cathode is negative from where the current leaves the diode. The colored band side is the indication that the side is the cathode and the other side without the colored band is the anode of the diode. Just stay with me for a little while as I’ll walk you through the 1n5408 power diode pinout, datasheet, features, equivalents, and applications. Let’s get started.

Introduction to 1N5408

  • The 1n5408 is a power diode where current flows in one direction only. It flows from the anode terminal to the cathode terminal. It carries low resistance in one direction and very high resistance in another direction.
  • It is a semiconductor device where two terminals are attached to the p-n junction.
  • The 1n5408 can be considered as an electronic check valve that allows current to flow in one direction only.
  • Available in the DO-201 package, this power diode comes with a peak reverse current of 10uA while forward voltage drop is equal to 1A. Plus, 1n5408 can support load under 3A and it can undergo a peak current of 200A.
  • There are two terminals on the diode named anode and cathode. The cathode terminal of the diode is identified by the grey colored band.
  • It is known as a power diode since it carries high repetitive reverse voltage and high forward current. It is best suitable for the circuits operating under 3A.
  • Due to the slow recovery time of this diode, this diode becomes obsolete in the modern circuits and is being replaced by advanced and highly efficient diodes.
  • The current-voltage characteristics are non-linear in this case of the diode. Moreover, it initiates current flow in one direction only when a certain threshold voltage is achieved in the forward direction.

1N5408 Datasheet

You can click the link below to get a datasheet where you can observe the main characteristics of the device.

1N5408 Pinout

The following figure shows the pinout diagram of 1n5408. The 1n5408 comes with two terminals known as anode and cathode. The anode terminal is the place where the current enters the device and a cathode terminal is a place where it leaves the diode.

In5408 Features

  • Available in DO-201 Package
  • High forward surge capability
  • Low leakage current.
  • Peak Reverse current = 10uA
  • Forward Voltage drop = 1V
  • Repetitive reverse voltage = 1000V
  • Non-repetitive Peak current = 200A
  • Average forward current = 3A

1N5408 Physical Dimensions

The following figure shows the physical dimensions of the device 1n5408.

1N5408 Applications

  • Used in HV supplies
  • Employed as a protection device
  • Incorporated in half-wave and full-wave rectifiers
  • Used in current flow regulators
  • Employed to prevent reverse polarity problem
That’s all for today. Hope you find this read helpful. If you have any questions, you can ask me in the comment section below. I’d love to help you the best way I can. Feel free to send your valuable suggestions and thoughts regarding the content we share, they help us generate quality content customized to your exact needs and requirements. Thank you for reading the article.

1N5822 Schottky Diode Pinout, Specifications, and Datasheet

Hello Guys! Hope you’re well today. Happy to see you around. I welcome you on board. In this post today, I’ll detail the Introduction to 1n5822. The 1n5822 is a Schottky diode that comes with a low forward drop voltage around 0.525V which means it needs 0.525 voltage to conduct the current in forward biased direction. It supports a load under 3A and is an ideal pick for switching applications with low current ratings. And the 40V is the maximum repetitive peak reverse voltage Vrrm of this tiny device. Just bear with me for just 2-min as I’ll be discussing the datasheet, Pinout, specifications, and applications of this tiny little device. Let’s get started.

Introduction to 1n5822

  • 1n5822 is a Schottky diode, also known as a hot-carrier diode, mainly used in fast-clamp diode switching applications. It is made up of semiconductor material and carries low forward drop voltage.
  • The small voltage drop occurs across the diode terminals when current flows through the diode.
  • Though both normal diode and Schottky require 2V DC source to power these components, the Schottky diode utilizes 0.3V out of 2V, leaving only 1.7V to power the diode while the normal diode uses 0.7V out of a 2V DC source, leaving 1.3V to power the diode.
  • Schottky diode is also called hot-carrier diode because electrons carry low energy when they are present on the semiconductor material in an unbiased condition.
  • This results in the formation of a barrier through which electrons cannot flow, the reason it’s also called the Schottky Barrier diode or hot carrier diode.

1n5822 Schottky Diode Construction

  • The 1n5822 Schottky diode is constructed by the combination of semiconductor material with metal, forming a barrier.
  • The metals used in this case are tungsten, chromium, platinum, molybdenum, and silicides.
  • And the n-type silicon is the commonly used semiconductor material. The resulting diode carries a very low forward voltage drop and is capable of very fast switching.
  • The metal used behaves as an anode or positive side of the diode and n-type semiconductor (with a colored band) is used as a cathode or negative side of the diode. In this case, the conventional current will flow from the anode metal side to the cathode semiconductor side.
  • The forward voltage of the diode depends on the nature of the metal and semiconductor you pick for the formation of that diode.
  • Though both n-type and p-type semiconductors are used to form a Schottky diode, the p-type semiconductors result in very low forward voltage compared to n-type semiconductors, the reason p-type semiconductors are rarely used to form the Schottky diodes.
  • In Schottky diodes less energy is wasted as heat as they possess low forward voltage drop, making them an ideal pick for the applications that are sensitive to efficiency.
  • Plus, they are also used in photovoltaic systems to keep the batteries from discharging in solar panels at night.
  • A control circuit or MOSFET can replace Schottky diodes in cases where less power dissipation is needed.

1n5822 Datasheet

Before you embed this component into your project, it’s always wise to weed through the datasheet of the device that gives the main characteristics of the device. Click below and download the datasheet of 1n5822.

1n5822 Pinout

1n5822 comes with two pins named anode and cathode. The colored band is a cathode and the other side is an anode. The following figure shows the pinout diagram of 1n5822. It is important to note that, the current always enters through an anode that is positive, and it leaves through a cathode that is negative in polarity.

1n5822 Features

  • Carries high efficiency and low power loss.
  • Conduction is carried out through majority carriers.
  • Protection against overvoltage.
  • Comes with low forward drop out voltage.
  • Capable of fast switching.
  • Available in package DO-201AD

1N5822 Applications

  • Used in low voltage & high-frequency inverters
  • Incorporated in freewheeling and DC/DC converters
  • Used to detect signals and polarity protection applications
  • Employed in logic circuits and radio frequency applications
  • Used in switching applications
  • Incorporated in sample-and-hold circuits
  • Employed to control the electronic charge
  • Incorporated in stand-alone photovoltaic systems
That’s all for today. I hope you find this read useful. If you have any question, you can pop your comment in the section below, I’ll answer your query according to the best of my expertise. You are most welcome to share your feedback and suggestions, they help us generate quality content. Thank you for reading the article.

1N5821 Schottky Diode Datasheet, Pinout, Features and Applications

Hi Friends! Happy to see you here. I welcome you on board. In this post today, I’ll walk you through the Introduction to 1n5821. The 1n5820 is a Schottky diode that carries high surge capability and low forward drop voltage. It helps in extremely fast switching and comes in the DO-201AD package. This diode is also known as a hot-carrier diode and is well-shielded against the overvoltage, keeping the device safe under desired ratings. I suggest you read this post all the way through as I’ll discuss the complete Introduction to 1n5821 covering the datasheet, features, pinout, features, and applications. Before further ado, let’s get started.

Introduction to 1N5821

  • The 1n5820 is a Schottky diode that is capable of extremely fast switching and is made by the combination of metal and semiconductor material.
  • In certain cases, where less power dissipation is required, MOSFETs replace these Schottky diodes.
  • Schottky diode is also called hot-carrier diodes since they form the barrier in an unbiased condition, blocking the electrons that carry low energy. This barrier formation is the reason these diodes are also known as hot-carrier diodes.
  • Schottky diode is slightly different than a regular diode. It is observed, both diodes are powered with a 2V DC source. Out of this 2V, the regular diode needs 0.7V and leaving 1.3V behind to provide power to the diode.
  • And Schottky diode needs 0.3V out of this 2V DC supply source, leaving behind 1.7V to give power to the diode.

1N5821 Datasheet

While using this device in your project, make sure you go through the datasheet of the device that covers the main characteristics of the device. You can download the datasheet by clicking the link below.

1N5821 Pinout

The following image represents the pinout diagram of the device 1n5821.
  • 1n5821 comes with two terminals known as anode and cathode. The cathode terminal is negative and is composed of semiconductor material while the anode terminal is positive and is made-up of metal.
  • The current always enters through the anode terminal and it leaves the diode from the cathode terminal. Current moves from the anode to the cathode terminal.

1N5821 Features

  • Highly efficient
  • Comes with small conduction losses.
  • Shielded against overvoltage.
  • Exhibits low forward drop voltage.
  • Extremely fast switching.
  • Comes with high surge capability.
  • Available in the DO-201AD package.

1n5821 Schottky Diode Construction

  • Semiconductor material and metal are required to form the Schottky diode. When the n-type semiconductor is combined with metals like chromium, platinum, tungsten, and molybdenum, they constitute a Schottky diode.
  • These diodes are incorporated in the solar systems that keep the batteries from discharging at night.
  • It is observed both n-type and p-type semiconductors material can be employed in the construction of Schottky diodes, but n-type materials are more beneficial than p-type materials because later comes with low drop voltage.
  • The semiconductor material and the metal used to form the Schottky diodes play a critical role in demonstrating the forward drop voltage of this device.
  • Low forward drop voltage leads to less energy released, making this tiny device appropriate pick suitable for high-efficiency applications.

1N5821 Applications

  • Used in high-frequency and fast switching applications.
  • Embedded in low voltage inverters and sample-and-hold circuits.
  • Control the electronic charge and can be used in polarity protection applications.
  • Used in DC/DC converters and logic circuits.
  • Incorporated in freewheeling and photovoltaic systems.
  • Embedded in signal detection and radio frequency applications.
This is it. That’s all about the Introduction to 1n5821. Share your valuable suggestions in the comment section below, they help us generate quality content. If you have any query, you can approach me in the section below, I’ll try to help you according to the best of my expertise. Thank you for reading the article.

MUR460 Rectifiers Datasheet, Features, Equivalent and Applications

Hi Folks! I welcome you on board. Thank you for clicking this read. In this post today, I’ll detail the Introduction to MUR460. The MUR460 is a switch-mode rectifier used in inverters, switching power supplies, and as a freewheeling diode. Just stay with me for a little while as I’ll be discussing the complete introduction to MUR460 covering pinout, features, working, and applications of this component. Let’s get started.

Introduction to MUR460

  • The MUR460 is a diode used as a rectifier in high frequency and freewheeling applications, in switching mode converters, and as an inverter in telecommunication.
  • When this p-n junction diode is used as a rectifier it coverts AC signals to DC signals. The rectifier diode provides an alternating voltage that changes with respect to time.
  • The p-n junction diode blocks current in reverse biased condition and allows the current to flow in forward biased condition only. Simply put, the p-n junction diode allows current to flow in one direction only and it blocks the current flowing in the opposite direction.
  • MUR460 comes with a working peak reverse voltage and a maximum repetitive peak reverse voltage of 600V. The maximum average forward rectified current is 4A. And the operating junction temperature range is -65 to 175 C.

MUR460 Datasheet

Before you employ this component into your project, just go through the datasheet of the device that details the main characteristics of the component. Click the link below and download the datasheet of the component MUR460.

MUR460 Pinout

The following figure shows the pinout diagram of MUR460.
  • This diode rectifier comes with two terminals called anode and cathode.
  • The anode side is positive through which current enters the diode and the cathode side is negative through which current leaves the diode and current moves from the anode terminal to the cathode terminal.
 

MUR460 Working

  • The working of this component is simple and straightforward. When the voltage is applied to the rectifier diode in such a way the negative terminal of the battery is attached with the n-type semiconductor and the positive terminal of the battery is connected to the p-type semiconductor material, in this condition the diode is forward biased.
  • In this forward biased condition, the free electrons available in the n-type region of the semiconductor experience a repulsive force, and a large number of holes present in the p-type semiconductor also experience a repulsive force.
  • In this case, the electrons due to this repulsive force start moving from the n-type region to the p-type region and the holes in the p-type region start moving to the n-type region.
  • And the conduction is carried out due to these charge carriers i.e. holes in the p-region and the electrons in the n-region.
  • As this conduction is the result of the movement of free majority charge carriers in the diode, the reason the current in the forward biased condition is also called the majority current.

MUR460 Features

The following are the features of this device MUR460.
  • Operating Junction Temperature = 175°C
  • Reverse Voltage = 600 V
  • Available in Tape and Reel
  • Carries low leakage current and low forward voltage
  • Ultrafast recovery times i.e. 25 ns, 50 ns, and 75 ns
  • High-temperature glass passivated junction
 

MUR460 Applications

  • Used in high-frequency rectification
  • Used in freewheeling applications
  • Employed in switching mode converters
  • Incorporated as an inverter in telecommunication
That was all about the Introduction to MUR460. If you’re unsure or have any questions, you can ask me in the comment section below. I’d love to help you the best way I can. Keep your valuable suggestions and feedback coming, they help us generate quality work customized to your exact needs and requirements. Thank you for reading this post.

1N5817 Schottky Diode Datasheet, Pinout, Features and Applications

Hi Guys! I welcome you on board. Glad to see you around. Thank you for clicking this read. In this post today, I’ll detail the Introduction to 1n5817. The 1n5817 is a Schottky diode used in extremely fast switching applications and carries high forward surge capability and low forward drop voltage. It is available in the DO-201AD package and can do high-frequency operations. Read this post till the end as I’ll discuss the complete introduction to 1n5817 covering the datasheet, pinout, features, and applications of this component. Let’s get started.

Introduction to 1N5817

  • The 1n5817 is a Schottky diode, also known as a hot-carrier diode, used in extremely fast switching applications.
  • It comes in the DO-201AD package and contains low forward drop voltage and high forward surge capability.
  • In some applications, less power dissipation is required, in that case, MOSFETs are used in place of Schottky diodes.
  • Schottky diode is also known as a hot-carrier diode due to the low electronic energy it exhibits in an unbiased condition.
  • This low energy develops the barrier that blocks the movement of electrons. This formation of the barrier is the reason Schottky diodes are also known as hot-carrier diodes.
  • Both Schottky diode and regular diode are the same in terms of current flow i.e. both allow current flow in one direction only and blocks it in the opposite direction.
  • But these diodes are different when it comes to the voltage needed to turn on these diodes. Both diodes get 2V DC source voltage, but the Schottky diode needs only 0.3V, where 1.7V is left behind to power up the diode. And normal diode needs 0.7V, where 1.3V is left out to power up the diode.

1N5817 Datasheet

Before you incorporate this component into your electrical circuit, it’s better to have a look at the datasheet of the device that comes with the power ratings of the component helping you better understand the main characteristics of the device. If you want to download the datasheet of 1n5817, click the link given below.

1N5817 Pinout

The following figure represents the pinout diagram of the 1n5817 Schottky diode.
  • This power diode comes with two terminals known as anode and cathode. Both terminals are used for the external connection with the electrical circuit.
  • The anode side is positive and the cathode side is negative. The current enters the diode from the anode terminal and it leaves the diode from the cathode terminal.
  • And current flows from the anode terminal to the cathode terminal. The diode only allows the current flow in one direction only i.e. from anode to cathode. It blocks the current flow from the cathode to the anode terminal.

1N5817 Features

  • Exhibits small conduction losses.
  • 1n5817 is highly efficient.
  • Well protected against overvoltage.
  • Used in extremely fast switching.
  • Available in package DO-201AD.
  • Contains high surge capability.
  • Contains low forward drop voltage.

1n5817 Schottky Diode Construction

  • The 1n5817 is constructed when the semiconductor material is mixed with the metal that creates the barrier.
  • When the metals like chromium, platinum, tungsten, and molybdenum are combined with the n-type semiconductor material, it results in the formation of Schottky diode. The n-type semiconductor is the material where electrons operate as a major charge carriers and holes work as minority carriers.
  • The Schottky diode contains two terminals called anode and cathode. The anode side is positive that is composed of metal material and the cathode side is negative that is made-up of semiconductor material. The current flows from the positive anode metal side to the cathode negative semiconductor side. Plus, the current enters the diode from the anode side and it leaves the diode from the cathode terminal.
  • Both n-type and p-type semiconductor material can be used to work as a cathode terminal in Schottky diode, but n-type materials are preferred over p-type material because the later comes with low drop voltage.
  • The forward drop voltage of the Schottky diode main depends on the nature of metal and semiconductor material used to form the barrier.

1N5817 Applications

  • Incorporated in sample-and-hold circuits.
  • Used in high-frequency and low voltage inverters.
  • Employed in polarity protection and DC/DC converters applications.
  • Used in freewheeling and logic circuits.
  • Used for signal detection and extremely fast switching applications.
  • Incorporated in solar systems.
  • Used to control the electronic charge.
  • Employed in radio frequency applications.
That was all about the Introduction to 1n5817. Hope you find this read helpful. If you’re unsure or have any question, you can pop your comment in the section below, I’ll help you the best way I can. Feel free to keep us updated with your valuable thoughts and suggestions, they help us generate quality content customized to your exact requirements. Thank you for reading this post.

LM2575 Buck Converter Datasheet, Pinout, Features, Applications

Hi Guys! Glad to see you around. I welcome you on board. In this post today, I’ll walk through the Introduction to LM2575. LM2575 is a step-down voltage regulator mainly used to step down the voltage. It is also known as a buck converter and is used to drive load under 1A. In the customized output version of the buck converter, you can set the output voltage as you like better. It comes with an extremely good load and line regulation and is available in fixed output voltages with 3.3V, 5V, and 12V. I suggest you read this post all the way through, as in this post I’ll detail the Introduction to LM2575 covering the datasheet, pinout, features, and applications of this component LM2575. Let’s get started.

Introduction to LM2575

  • LM2575 is a voltage regulator and simplified version of switching power supplies that carry all functions required to step down the voltage in the circuit.
  • This buck converter is incorporated with an integrated switch that can support load under 1A.
  • LM2575 carries an excellent load line and load regulation. It comes in two versions: fixed output voltage version with voltage 3.3V, 5V, 12V, and adjustable output version that gives the ability to pick your desired output.
  • It is also called the DC-to-DC power converter employed to step down the voltage from its input supply to its output load. The current increases during this voltage regulation.
  • This regulator is integrated with a fixed-frequency oscillator of about 52 kHz and an in-built frequency compensation method.
  • Frequency compensation is applied to reduce vibration and oscillation in the circuit. It can be obtained using resistance-capacitance networks.
  • Apart from the remarkable load and line regulation, this device comes with a manual shutdown option through an external ON/OFF pin.
  • Less external components are needed for this buck converter since it works at a fixed frequency of 52 kHz.

LM2575 Features

  • Fixed versions with 3.3-V, 5-V, 12-V, and adjustable output versions
  • Adjustable output version with voltage range: 1.2-V to 37-V ±4% maximum over load and line conditions
  • Available in two packages named TO-263 and TO-220 packages.
  • Can drive load under 1A.
  • Comes with low power standby mode, commonly less than 200 µA.
  • Uses easily available standard inductors and is highly efficient.
  • 4.75 to 40 V is the input voltage range.
  • 23V to 37V is the output voltage range.
  • 80% efficiency.
  • Excellent load and line regulations.
  • Fixed internal oscillator frequency of 52 kHz.
  • TTL shutdown capability.
  • Protection against overcurrent and thermal shutdown.

LM2575 Pinout

LM2575 comes with five terminals. The following figure shows the pinout diagram of LM2575. ON/OFF = I = this terminal can shut down the voltage regulator circuit with input supply current decreasing to 50uA. Its working is simple and straightforward. When the voltage available on this pin is turned below the threshold voltage of 1.3V, it results in turning on the voltage regulator. And when the voltage is turned above the 1.3V, it results in turning off the voltage converter. You can remove this shutdown feature by connecting the pin to the ground or leaving it open. In both cases, the regulator will be turned ON. VIN = I = this is the 16 number input terminal attached with the input bypass capacitor to reduce voltage transients and to provide the switching current. Output = O = this is the 3 number pin that acts like an internal switch where voltage switches between (Vin – Vsat) and -0.5V. The duty cycle on this pin is Vout/Vin. The PCB copper area connected to this pin is mainly used to reduce the coupling. Ground = three pins number 5,12 & 13 are attached to the ground. Feedback = I = this is the 7 number pin that indicates the regulated output voltage for the feedback loop.

LM2575 Datasheet

Before you install this component into your project, it’s wise to scan through the datasheet that covers the main characteristics of the component. Click the link below and download the datasheet of LM2575.

LM2575 Applications

LM2575 is used in the following applications.
  • Used in a simple efficient step-down regulator.
  • Used as a pre-regulator in linear regulator
  • Used to drive load under 1A.
  • Incorporated in On-card switching regulators.
  • Employed in a positive-to-negative converter.
That was all about the Introduction to LM2575. Hope you find this post helpful. If you have any query, you can approach me in the section below, I’d love to help you the best way I can. Feel free to keep us updated with your valuable feedback and suggestions, they help us produce quality content customized to your exact needs and requirements. Thank you for reading the article.

Introduction to TIP42

Hi Guys! Thank you for clicking this read. Hope this finds you well. In this post today, I’ll document the Introduction to Tip42. Tip42 is a medium power silicon transistor mainly used for switching and amplification purpose. It belongs to the PNP transistor family and comes in the TO-220 package. The collector current is 6A which signals it can support load under 6A. Both collector-base and the collector-emitter voltages are 40V. And the only 5V is required to initiate the transistor action as the emitter-base voltage is 5V. The power dissipation is 65W which defines the amount of energy released during the working of this transistor. The storage junction temperature is -65 to 150C and transition frequency is 3MHz. Just stay with me for 2-min as I’ll be discussing the main features, pinout, datasheet, and applications of the device Tip42. Let’s jump right in.

Introduction to TIP42

    • Tip42 is an epitaxial medium power silicon transistor mainly used for switching and amplification purpose. It falls under the category of PNP transistor and comes with current gain ranging from 15 to 75.
    • This current gain demonstrates the capacity of transistor it can amplify the current. It’s a ratio between the output current and input current.
    • Tip42 is a bipolar transistor which means two charge carriers are used in the conductivity process inside the transistor.
    • Both electrons and holes take part in the conductivity process. And in this case of PNP transistor, holes are majority carriers. And electrons are minority carriers in the case of NPN transistors.
  • This PNP transistor contains three terminals called the emitter, base, and collector. All these terminals carry different functionality and different doping concentration.
  • This different doping concentration is the main reason this bipolar transistor is not symmetrical. The external circuit is connected with the transistor through these terminals.
  • Tip42 is composed of two p-doped layers and one n-doped layer. The n-doped layer is sandwiched between the two p-doped layers. The two p-layers represent the collector and emitter terminals and the n-layer represents the base terminal. The N sign shows, a negative voltage is applied on the base terminal to trigger and start the transistor action.
  • This bipolar transistor controls the small input current and produces the large output current, the reason these devices are called current-controlled devices because two charge carriers are used for conductivity in contrast to FETs(field effect transistor) which is unipolar voltage-controlled devices. Where conductivity is carried out with only one charge carrier.
 

TIP42 Features

The following are the main features of transistor BC538.
  • Package: TO-220
  • Material: Silicon
  • Type – PNP
  • Emitter-Base Voltage: 5 V
  • Collector-Base Voltage: 40 V
  • Collector-Emitter Voltage: 40 V
  • Collector Dissipation: 65 W
  • Collector Current: 6 A
  • Transition Frequency: 3 MHz
  • Current Gain (hfe): 15 to 75
  • Storage Junction Temperature: -65 to +150 °C
  These are the main features and absolute maximum ratings of the device Tip42. Make sure you don’t apply these ratings for more than the required time, otherwise it will harm your device reliability.
  • Plus, make sure your ratings don’t exceed these absolute maximum ratings while you’re working with the device, otherwise they will badly damage the device and thus the entire project.
  • Both collector-emitter and collector-base voltages are 40V while the emitter-base voltage is 5V which projects you need to apply 5V to initiate the transistor action.
  • The Collector current is 6V which indicates this transistor can support load under 6A. The transition frequency is 3MHz and power dissipation is 65W which is the amount of energy released during the working of this transistor.
  • DC common-emitter current gain ranges from 15 to 75. It is a ratio between collector current and base current. This describes the capacity of transistors it can amplify the current. This is a relation between output amplified current to input small current.
  • Another important current gain is the common-base current gain which is a ratio between collector current and emitter current and its value is always less than one. Normally ranges from 0.5 to 0.95.
  • The small current at one pair of terminals is used to produce large current across other pairs of terminals of the transistor and this process is used for amplification purposes.
  • It is important to note that the PNP transistors are less likely to employ for amplification purposes than NPN transistors. Because the mobility of electrons in the NPN transistor is far better and quicker than the mobility of holes in PNP transistors.
 

TIP42 Pinout

The Tip42 consists of three main terminals called: 1: Base 2: Collector 3: Emitter The following figure shows the pinout diagram of Tip42.
  • The collector terminal is lightly doped and the emitter terminal is highly doped in contrast to the other two terminals.
  • The collector terminal is 10-times lightly doped than the base terminal. And this transistor is manufactured in such a way, the collector side covers the entire emitter terminal area.
  • The base terminal is responsible for the entire transistor action.
  • This base terminal acts like a control valve that controls the number of holes in the case of the PNP transistor and the number of electrons in the case of NPN transistor.
  • When 5V is applied at the base terminal, it gets biased and starts the transistor action where current moves from emitter to collector terminal which is the opposite in the case of NPN transistors where current moves from collector to emitter terminal. And in both cases base terminal controls the amount of current passing through it.

TIP42 Datasheet

Before you apply this device into your project, scan through the datasheet of the component that helps you get a hold of the main characteristics of the device. You can download the datasheet of Tip42 by clicking the link below.

TIP42 Applications

Tip42 is used in the following applications.
  • Used for switching and amplification purpose.
  • Used to drive load under 6A.
  • Incorporated in the motor control circuit
  • Employed in H-bridge circuit
  • Incorporated in the voltage regulator circuit
That’s all for today. I hope you’ve got a clear insight into the Introduction to Tip42. If you’re unsure or have any question, you can pop your question in the comment section below, I’d love to assist you the best way I can. Keep your suggestions and feedback coming, they help us create quality content customized to your exact needs and requirements. Thank you for reading the article.

Introduction to TIP42C

Hi Friends! I welcome you on board. Happy to see you around. In this post, I’ll detail the Introduction to Tip42c. Tip42c is a medium power transistor mainly used for amplification and switching purpose. It is made up of silicon material and falls under the category of PNP transistors. The voltage across collector and emitter terminals is 100V and the voltage across base and collector terminals is 100V. The 5V is the voltage across base and emitter terminals which projects the value of voltage required to bias this transistor. The 6A is collector current which indicates the value of loads this transistor can support. Just bear with me for a little while as I’ll be documenting the main features, pinout, applications, and datasheet of this tiny component Tip42c.

Introduction to TIP42C

  • Tip42c is a PNP medium power bipolar transistor mainly used for switching and amplification purpose.
  • It is composed of silicon material and comes in the TO-220 package.
  • It comes with three pins called the emitter, base, and collector. These pins are also known as transistor terminals that are connected with the external electrical circuit.
  • The small input current across one pair of terminals is used to generate large output current across other pairs of terminals.
  • Tip42c contains three layers where two are p-doped silicon layers and one is an n-doped silicon layer. The n-doped layer represents the base terminal where negative voltage is applied to start the transistor action. The two p-doped layers surround the n-doped layer.
  • As this bipolar transistor controls the small current to produce large current, the reason bipolar transistors are considered as a current-controlled device in contrast to FETs(field effect transistor) which is a unipolar transistor (conductivity happens due to one charge carrier) that are voltage-controlled devices.
  • Two current-gains are important while studying bipolar transistors. One is a common-emitter current gain which ranges from 15 to 75 in this case and common-base current gain which is a ratio between collector current to emitter current, this is normally called alpha.
Its value is always less than 1, commonly lies from 0.90 to 0.95 but more often than not its value is taken as unity.  

TIP42C Features

The following are the main features of device Tip42c
  • Name: TIP42C
  • Package: TO220
  • Material used: Silicon
  • Type: PNP
  • Power Dissipation: 65 W
  • Collector-Base Voltage = Vcb: 100 V
  • Collector-Emitter Voltage = Vce: 100 V
  • Emitter-Base Voltage = Veb: 5 V
  • Collector Current = Ic : 6 A
  • Operating Junction Temperature = Ti:  -65 to 150 °C
  • Transition Frequency = ft: 3 MHz
  • Common-emitter current gain = hfe: 15 to 75
These are the main features and the power ratings of the transistor Tip42c. Don't apply these ratings for more than the desired time, else they will influence the device reliability.
  • The Tip42c is a bipolar transistor which means two charge carriers are used for the conduction process inside the transistor. Both electrons and holes are used for the conductivity, however, holes are the majority carriers and electrons are the minority carriers. Which is the opposite in the case of NPN transistor where electrons are the majority carriers and holes are minority carriers.
  • This PNP transistor comes in TO-220 package with collector current 6A which demonstrates it can support the loads under 6A.
  • The junction temperature ranges from -65 to 150C and the transition frequency is 3MHz which is a measure of the transistor’s high frequency operating characteristics. It is denoted by ft.
  • The common-emitter current gain stands from 15 to 75 which is the capacity of the transistor it can amplify the small input current. It is called beta and is a ratio between output collector current to input base current.
  • And the only 5V is required to start the transistor action because 5V is the voltage across emitter and base terminals.
  • It is important to note that this PNP transistor is not preferred over its counterpart NPN transistor because the mobility of electrons in the NPN transistors is quicker and better than the mobility of holes inside the PNP transistor.
  • Moreover, in NPN transistors the current flows from the collector side to the emitter side in contrast to PNP transistors where current moves from the emitter side to the collector side.
  • The 65W is the power dissipation that indicates the energy released when this transistor starts working in the electrical circuit. This varies from transistor to transistor.

TIP42C Pinout

The Tip42c contains three terminals named: 1: Base 2: Collector 3: Emitter The following diagram shows the pinout of the transistor Tip42c.
  • All these terminals carry different doping concentrations and different working ability. The emitter side is more doped compared to the other two terminals and the collector side is lightly doped. The base side is 10-times more doped than the collector terminals.
  • This bipolar transistor is not symmetrical. This absence of symmetry is due to the different doping concentration of the emitter and collector terminals.
  • In bipolar transistors, the base terminal is responsible for the entire transistor action. When voltage is applied at the base terminal, it gets biased and starts controlling the number of holes in this case of PNP transistors and the number of electrons in the case of NPN transistors.
  • This base terminal acts like a control valve that controls the amount of current. The emitter terminal is highly doped and contains the entire current of the transistor. The emitter current is equal to the sum of the collector current and base current.
 

TIP42C Datasheet

When you’re working with tiny devices like Tip42c, it is wise to scan through the datasheet of the component that documents the main characteristics of the transistor. Click the link below and download the datasheet of Tip42c.

TIP42C Applications

The Tips42c is used in the following applications.
  • Used for switching and amplification applications
  • Used in motor control drivers
  • Employed in H-bridge circuits
  • Incorporated in voltage regulator circuits
  • Used to drive loads under 6A
That’s all for today. I hope you find this article helpful. If you’re unsure or have any question, you can pop your query in the section below, I’d love to help you the best way I can. Feel free to leave your valuable suggestions and feedback, they assist us to generate quality content customized to your exact requirements. Thank you for reading the article.

Introduction to C1815

Hello friends, I hope you all are doing great. In today's tutorial, we are gonna have a look at detailed Introduction to C1815. The C1815 is a transistor like other it is used to amplify acoustic frequency signal. Most transistors are coded for easy documentation through these titles can differ by builders. One or two erudition are typically trailed by a sequence of statistics, and then probably additional statistics. Consequently, a C1815 transistor can also be recognized as a 2SC1815 transistor. It is used as a switch to initiative loads below 150mA. The use of transistors aided the electronics manufacturing alteration quickly, and developments in expertise are permitting minor apparatuses to be used to production of slighter expedients. In today’s post, we will have a look at its shield, wreckages, implication, proposals, etc. I will also share some links where I have connected it with other microcontrollers. You can also get more material about it in comments, I will guide you more about it. So, let’s get started with a basic Introduction to C1815

Introduction to C1815

  • The C1815 is a transistor like other it is used to amplify acoustic frequency signal. It is used as a switch to initiative loads below 150mA.
  • It is manufactured from semiconductors constituents such as Silicon, Germanium, etc, it has three pinouts sometime extra.
  • It is used for swapping and strengthening of numerous signals. Additional statistics can also be found only from the part digits.
  • The '2S' ratio of the integer designates that the C1815 transistor is decent for high-frequency solicitations and is in Negative-Positive-Negative arrangement.

  • The first negative terminal of the transistor is associated with the negative sideways of a circuit, and monitor the movement of electrons to the positive area in the intermediate.

  • The second negative terminal of the transistor governs the electrons sendoff the positive, central area.

  • The semiconductor component that is used to develop the transistor decide that the transistor have NPN or PNP pattern.
  • Three leads on this transistor recognized the emitter, base, and collector. An emitter is a yield, the base is similar to the doorway which switches the input of the collector.
  • For instance, while a C1815 transistor is used in an audiovisual solicitation, the emitter directs the audiovisual output signal. This is managed by the base, which can be a squat audiovisual signal, and motorized by the collector, which might be a 5-volt power source.
  • By fluctuating the quantity of current at the base terminal of a transistor, the extent of power moving from the collector to the emitter can be organized.
  • For illustration, in numerical circuits, a transistor is on condition when it accepts 5-volts, and off when it takes fewer than that quantity.
  • Overall evaluations for a C1815 transistor comprise a power indulgence of 0.4 watts at an ambient temperature of 77° Fahrenheit (25° Celsius). The transistor consumes collector current of 0.15 amps. Quantity of voltage amid collector and base is 60 volts.

Pinout of C1815

  • These are pinout of C1815.
    Pin# Type                                         Parameters
    Pin#1 Emitter This pin is for the outward movement of current.
    Pin#2 Base The base governs the biasing of the transistor.
    Pin#3 Collector The collector is for the current inner drive. It is associated with the load.
    Lest see a diagram of the pinout.

Features of C1815

  • These are some features of C1815.
    • It is offered in cascading of TO-92.
    • It is like an NPN transistor.
    • The quantity of current across collector (Ic) is 150mA.
    • The value of voltage across the collector to the emitter(VCE) is 50V.
    • The quantity of voltage crossways its emitter and base (VEB) is 5V.
    • Voltage crosswise collector and base (VCB) is 60V.
    • Intemperance power crossways collector is 400mW.
    • Its frequency conversion is 80MHZ.
    • It lowermost current gain is 70 and extreme is 700.
    • Its extreme stowage and the employed temperature is -55 to +150 C.

Where we can use C1815

  • As it is C1815 transistor it can be used in acoustic intensifications phases, trivial acoustic amplifier, pre-amplifier and also in pre-amplifier phases.
  • It works as a switch in electronic circuits to run loads of 150mA such as to run relay, high power consuming transistors, LEDs and other industrial electronic circuits.
  • It works as a switch in electronic circuits to run loads of 150mA such as to run relay, high power consuming transistors, LEDs and other industrial electronic circuits.
  • We can use it to construct a Darlington pair.

Applications of C1815 

  • These are applications of C1815.
    • It is used in such instruments which use Sensor Circuits
    • It is used in Auditory Pre-amplifiers.
    • It is used in different audio Amplifier Phases.
    • It works as a switch for such circuits which use 150mA current.
    • It used in RF Circuits.
 So it was all about C1815 if you have any question about it ask in comments. I will explain to you further about it. Thanks for reading.
Syed Zain Nasir

I am Syed Zain Nasir, the founder of <a href=https://www.TheEngineeringProjects.com/>The Engineering Projects</a> (TEP). I am a programmer since 2009 before that I just search things, make small projects and now I am sharing my knowledge through this platform.I also work as a freelancer and did many projects related to programming and electrical circuitry. <a href=https://plus.google.com/+SyedZainNasir/>My Google Profile+</a>

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Syed Zain Nasir