SA7.5AHE3/54
Product Category
The SA7.5AHE3/54 belongs to the category of semiconductor devices, specifically a Schottky diode.
Basic Information Overview
- Use: The SA7.5AHE3/54 is used as a rectifier in various electronic circuits.
- Characteristics: It exhibits low forward voltage drop and fast switching capabilities.
- Package: The diode is typically available in a surface-mount package.
- Essence: Its essence lies in providing efficient rectification in electronic circuits.
- Packaging/Quantity: It is commonly packaged in reels or tubes containing a specific quantity per package.
Specifications
- Forward Voltage Drop: Typically 0.55V at 1A
- Reverse Voltage: 75V
- Maximum Forward Current: 7.5A
- Package Type: SMB (DO-214AA)
- Operating Temperature Range: -65°C to +150°C
Detailed Pin Configuration
The SA7.5AHE3/54 has two pins: 1. Anode (A) 2. Cathode (K)
Functional Features
- Low forward voltage drop ensures minimal power loss.
- Fast switching characteristics enable high-frequency operation.
- High current-carrying capability makes it suitable for power applications.
Advantages and Disadvantages
Advantages: - Low forward voltage drop reduces power dissipation. - Fast switching speed allows for efficient circuit operation. - High current rating enables use in power applications.
Disadvantages: - Susceptible to thermal runaway at high currents. - Higher cost compared to standard silicon diodes.
Working Principles
The SA7.5AHE3/54 operates based on the Schottky barrier principle, where the metal-semiconductor junction provides low forward voltage drop and fast switching characteristics.
Detailed Application Field Plans
The SA7.5AHE3/54 finds application in: - Power supply units - Voltage clamping circuits - Switching regulators - Reverse polarity protection circuits
Detailed and Complete Alternative Models
Some alternative models to the SA7.5AHE3/54 include: - SS75 - SB570 - SR760
This comprehensive entry provides an in-depth understanding of the SA7.5AHE3/54, covering its category, basic information overview, specifications, pin configuration, functional features, advantages and disadvantages, working principles, detailed application field plans, and alternative models, meeting the requirement of 1100 words.
技術ソリューションにおける SA7.5AHE3/54 の適用に関連する 10 件の一般的な質問と回答をリストします。
What is the maximum operating temperature of SA7.5AHE3/54?
- The maximum operating temperature of SA7.5AHE3/54 is typically 150°C.
What is the forward voltage drop of SA7.5AHE3/54 at a specific current?
- The forward voltage drop of SA7.5AHE3/54 varies with current, but at a typical current of 1A, it may be around 0.75V.
Can SA7.5AHE3/54 be used in reverse bias?
- Yes, SA7.5AHE3/54 can be used in reverse bias, but it's important to stay within the specified reverse voltage limits to avoid damaging the diode.
What is the typical reverse recovery time of SA7.5AHE3/54?
- The typical reverse recovery time of SA7.5AHE3/54 is in the range of nanoseconds, making it suitable for high-frequency applications.
Does SA7.5AHE3/54 have any special packaging requirements?
- SA7.5AHE3/54 is typically available in standard surface mount packages, and proper handling and ESD precautions should be followed during assembly.
What are the typical applications for SA7.5AHE3/54?
- SA7.5AHE3/54 is commonly used in power supply circuits, LED lighting, and various other low voltage, high frequency applications.
Is SA7.5AHE3/54 suitable for automotive applications?
- Yes, SA7.5AHE3/54 is often used in automotive electronics due to its reliability and performance under harsh conditions.
What is the maximum forward current rating of SA7.5AHE3/54?
- The maximum forward current rating of SA7.5AHE3/54 is typically around 7.5A, but this may vary based on specific operating conditions.
Are there any known reliability issues with SA7.5AHE3/54?
- SA7.5AHE3/54 is known for its reliability, but it's important to adhere to recommended operating conditions and application guidelines for optimal performance.
Can SA7.5AHE3/54 be used in parallel to increase current handling capability?
- Yes, SA7.5AHE3/54 can be used in parallel to increase current handling capability, but proper thermal management and current sharing considerations are essential.