MA-COM MA4P789ST-287T

having leads that are designed to be soldered on the side of a circuit board that the body of the component is mounted on.

The parameter "Diode Element Material" refers to the specific semiconductor material used in the construction of a diode. This material determines the electrical characteristics and performance of the diode, including its forward voltage drop, reverse breakdown voltage, and switching speed. Common diode element materials include silicon, germanium, and gallium arsenide, each offering different advantages for various applications. The choice of material impacts the diode's efficiency, thermal stability, and overall suitability for specific electronic circuits.

The "Pbfree Code" parameter in electronic components refers to the code or marking used to indicate that the component is lead-free. Lead (Pb) is a toxic substance that has been widely used in electronic components for many years, but due to environmental concerns, there has been a shift towards lead-free alternatives. The Pbfree Code helps manufacturers and users easily identify components that do not contain lead, ensuring compliance with regulations and promoting environmentally friendly practices. It is important to pay attention to the Pbfree Code when selecting electronic components to ensure they meet the necessary requirements for lead-free applications.

The parameter "Applications" in electronic components refers to the specific uses or functions for which a component is designed. It encompasses various fields such as consumer electronics, industrial automation, telecommunications, automotive, and medical devices. Understanding the applications helps in selecting the right components for a particular design based on performance, reliability, and compatibility requirements. This parameter also guides manufacturers in targeting their products to relevant markets and customer needs.

Any Feature, including a modified Existing Feature, that is not an Existing Feature.

HTS (Harmonized Tariff Schedule) codes are product classification codes between 8-1 digits. The first six digits are an HS code, and the countries of import assign the subsequent digits to provide additional classification. U.S. HTS codes are 1 digits and are administered by the U.S. International Trade Commission.

In electronic components, the term "Terminal Position" refers to the physical location of the connection points on the component where external electrical connections can be made. These connection points, known as terminals, are typically used to attach wires, leads, or other components to the main body of the electronic component. The terminal position is important for ensuring proper connectivity and functionality of the component within a circuit. It is often specified in technical datasheets or component specifications to help designers and engineers understand how to properly integrate the component into their circuit designs.

Occurring at or forming the end of a series, succession, or the like; closing; concluding.

Peak Reflow Temperature (Cel) is a parameter that specifies the maximum temperature at which an electronic component can be exposed during the reflow soldering process. Reflow soldering is a common method used to attach electronic components to a circuit board. The Peak Reflow Temperature is crucial because it ensures that the component is not damaged or degraded during the soldering process. Exceeding the specified Peak Reflow Temperature can lead to issues such as component failure, reduced performance, or even permanent damage to the component. It is important for manufacturers and assemblers to adhere to the recommended Peak Reflow Temperature to ensure the reliability and functionality of the electronic components.

Reach Compliance Code refers to a designation indicating that electronic components meet the requirements set by the Registration, Evaluation, Authorization, and Restriction of Chemicals (REACH) regulation in the European Union. It signifies that the manufacturer has assessed and managed the chemical substances within the components to ensure safety and environmental protection. This code is vital for compliance with regulations aimed at minimizing risks associated with hazardous substances in electronic products.

a count of all of the component leads (or pins)

JESD-30 Code refers to a standardized descriptive designation system established by JEDEC for semiconductor-device packages. This system provides a systematic method for generating designators that convey essential information about the package's physical characteristics, such as size and shape, which aids in component identification and selection. By using JESD-30 codes, manufacturers and engineers can ensure consistency and clarity in the specification of semiconductor packages across various applications and industries.

An indicator of formal certification of qualifications.

The parameter "Configuration" in electronic components refers to the specific arrangement or setup of the components within a circuit or system. It encompasses how individual elements are interconnected and their physical layout. Configuration can affect the functionality, performance, and efficiency of the electronic system, and may influence factors such as signal flow, impedance, and power distribution. Understanding the configuration is essential for design, troubleshooting, and optimizing electronic devices.

In electronic components, the parameter "Diode Type" refers to the specific type or configuration of a diode, which is a semiconductor device that allows current to flow in one direction only. There are various types of diodes, each designed for specific applications and functions. Common diode types include rectifier diodes, zener diodes, light-emitting diodes (LEDs), and Schottky diodes, among others. The diode type determines the diode's characteristics, such as forward voltage drop, reverse breakdown voltage, and maximum current rating, making it crucial for selecting the right diode for a particular circuit or application. Understanding the diode type is essential for ensuring proper functionality and performance in electronic circuits.

Breakdown Voltage-Min, also known as minimum breakdown voltage, is a crucial parameter in electronic components, especially in devices like diodes, transistors, and capacitors. It refers to the minimum voltage at which the component experiences a breakdown and allows a significant current to flow through it. This breakdown voltage is a critical threshold beyond which the component may get damaged or exhibit unexpected behavior. Manufacturers specify this parameter to ensure that the component operates within safe limits and to help designers select the appropriate components for their circuit requirements. It is essential to consider the Breakdown Voltage-Min when designing circuits to prevent overloading or damaging the components.

Frequency band refers to a range of frequencies within the electromagnetic spectrum that a particular electronic component or device is designed to operate within. It is a crucial parameter that determines the performance and functionality of the component. The frequency band specifies the upper and lower limits of frequencies that the component can effectively transmit, receive, or process signals. Components such as antennas, filters, amplifiers, and transceivers are designed with specific frequency bands in mind to ensure optimal performance and compatibility with other components in a system. Understanding the frequency band of electronic components is essential for designing and integrating them into electronic systems for efficient and reliable operation.

The parameter "Diode Capacitance-Max" refers to the maximum capacitance value that a diode can exhibit under specified conditions. Capacitance in a diode is a measure of its ability to store and release electrical charge, which can affect the diode's performance in certain applications. A higher capacitance value can lead to slower response times and increased signal distortion in high-frequency circuits. It is important to consider the maximum capacitance of a diode when designing electronic circuits to ensure proper functionality and performance.

The parameter "Minority Carrier Lifetime-Nom" in electronic components refers to the average time it takes for minority carriers (electrons or holes) to recombine in a semiconductor material. This parameter is crucial in determining the overall performance and efficiency of electronic devices, particularly in applications such as transistors, diodes, and solar cells.A longer minority carrier lifetime typically indicates better material quality and lower recombination rates, leading to improved device performance and reduced energy losses. Manufacturers often provide a nominal value for this parameter to help engineers and designers understand the expected behavior of the component under specific operating conditions.By optimizing the minority carrier lifetime, engineers can enhance the speed, efficiency, and reliability of electronic devices, ultimately contributing to advancements in technology and innovation in various industries.

Diode Res Test Current is a specification that indicates the current level used to test the resistance of a diode in reverse bias. This parameter helps determine the diode's leakage current and overall condition by measuring its resistance when a specific reverse current is applied. A higher resistance value at this test current usually indicates that the diode is functioning properly, while lower values may suggest degradation or failure.

The parameter "Diode Forward Resistance-Max" refers to the maximum resistance that a diode exhibits when it is forward-biased. When a diode is forward-biased, it allows current to flow in the forward direction, and the diode's resistance in this direction is known as the forward resistance. This parameter is important because it indicates how effectively the diode conducts current when it is in the forward-biased state. A lower forward resistance value indicates that the diode can conduct current more efficiently, while a higher value means that there will be more resistance to the flow of current through the diode.