Kycon, Inc. SX4020

The parameter "Housing Material" in electronic components refers to the material used to encase or protect the internal circuitry of the component. The housing material plays a crucial role in providing physical protection, insulation, and environmental resistance to the electronic component. Common housing materials include plastics, metals, ceramics, and composites, each offering different levels of durability, heat resistance, and electrical properties. The choice of housing material is important in determining the overall performance, reliability, and longevity of the electronic component in various operating conditions.

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.

In electronic components, the "Series" refers to a group of products that share similar characteristics, designs, or functionalities, often produced by the same manufacturer. These components within a series typically have common specifications but may vary in terms of voltage, power, or packaging to meet different application needs. The series name helps identify and differentiate between various product lines within a manufacturer's catalog.

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

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

In the context of electronic components, the parameter "Gender" typically refers to the physical characteristics of connectors or interfaces that determine how they can be mated together. Connectors are often designed with specific gender types, such as male or female, to ensure proper alignment and connection between devices. A male connector typically has protruding pins or plugs that fit into a corresponding female connector, which has receptacles or sockets to receive the pins. This design helps prevent incorrect connections and ensures a secure and reliable electrical connection. Understanding the gender of connectors is crucial when designing or assembling electronic systems to ensure compatibility and proper functionality. It is essential to match the gender of connectors correctly to avoid damage and ensure optimal performance of the electronic components.

The parameter "Current Rating (Amps)" in electronic components refers to the maximum amount of electrical current that the component can safely handle without being damaged. It is typically measured in amperes (A) and is an important specification to consider when designing or selecting components for a circuit. Exceeding the current rating of a component can lead to overheating, malfunction, or even failure of the component. It is crucial to ensure that the current rating of a component matches the requirements of the circuit to prevent any potential issues and ensure reliable operation.

In electronic components, "Pitch" refers to the distance between the center of one pin or lead to the center of the adjacent pin or lead on a component, such as an integrated circuit (IC) or a connector. It is a crucial parameter as it determines the spacing and alignment of the pins or leads on a component, which in turn affects how the component can be mounted on a circuit board or connected to other components.The pitch measurement is typically expressed in millimeters (mm) or inches (in) and plays a significant role in determining the overall size and layout of a circuit board. Components with different pitches may require specific types of circuit boards or connectors to ensure proper alignment and connection. Designers must carefully consider the pitch of components when designing circuit layouts to ensure compatibility and proper functionality of the electronic system.

In the context of electronic components, the term "Reference Standard" typically refers to a specific set of guidelines, specifications, or requirements that serve as a benchmark for evaluating the quality, performance, and characteristics of the component. These standards are established by organizations such as the International Electrotechnical Commission (IEC), the Institute of Electrical and Electronics Engineers (IEEE), or specific industry bodies.Reference standards help ensure consistency and interoperability among different components, as they provide a common framework for manufacturers, designers, and users to adhere to. They outline parameters such as electrical properties, mechanical dimensions, environmental conditions, and safety considerations that the component must meet to be considered compliant.By referencing these standards, manufacturers can design and produce components that meet industry-recognized criteria, which in turn helps users select the right components for their applications with confidence. Adhering to reference standards also facilitates regulatory compliance and promotes overall quality and reliability in electronic systems.

Contact finish refers to the surface coating or treatment applied to the electrical contacts of electronic components. This finish is crucial for ensuring reliable electrical connections and preventing corrosion or oxidation of the contacts. Common contact finishes include gold, silver, tin, and nickel, each offering different levels of conductivity, durability, and resistance to environmental factors. The choice of contact finish depends on the specific application requirements, such as operating conditions, cost considerations, and compatibility with other components in the circuit. Selecting the appropriate contact finish is essential for maintaining the performance and longevity of electronic devices.

Reliability in electronic components refers to the ability of a component to perform its required functions under stated conditions for a specified period of time. It is a measure of the likelihood that a component will not fail during its intended lifespan. High reliability indicates that the component is less likely to experience unexpected failures, which is crucial for maintaining the overall performance and safety of electronic systems. Factors affecting reliability include material quality, manufacturing processes, and environmental conditions.

Body length or diameter in electronic components refers to the physical dimensions of a component's housing, typically measured in millimeters or inches. It indicates the size of the component that affects its fit within a circuit board or system. This parameter is crucial for ensuring compatibility with the design and mounting of electronic devices. It can impact heat dissipation, electrical performance, and overall assembly efficiency. Accurate measurement of body length or diameter is essential for proper component selection and placement in electronic applications.

Body breadth in electronic components refers to the width of the physical body of a component, such as a resistor, capacitor, or integrated circuit. This measurement is crucial for ensuring proper fit within a circuit board or enclosure. It can affect the component's thermal performance, mechanical stability, and overall compatibility with other components in a design. Body breadth is typically specified in millimeters or inches and is an important factor in the selection and design of electronic assemblies.

Body Depth is a parameter that refers to the physical measurement of the depth or thickness of an electronic component. It is typically measured from the bottom to the top of the component, excluding any external connectors or pins. Body Depth is an important specification as it determines how much space the component will occupy on a circuit board or within an electronic device. Manufacturers provide this measurement to help designers and engineers ensure proper fit and compatibility within their designs. Understanding the Body Depth of electronic components is crucial for efficient and effective integration into electronic systems.

The parameter "Contact Style" in electronic components refers to the specific design and arrangement of the contact points that enable electrical connection in various devices. It dictates how components interface with each other, affecting factors such as reliability, durability, and performance. Different contact styles can include configurations like pin, socket, blade, or surface mount, each designed to cater to specific applications and requirements in circuit assembly.

Contact resistance refers to the resistance encountered at the point of contact between two conductive materials or components. It is a measure of how well the two materials make electrical contact with each other. High contact resistance can lead to voltage drops, power losses, and inefficient electrical connections. It is typically measured in ohms and is an important parameter to consider in electronic components such as connectors, switches, and relays. Lower contact resistance is desirable for ensuring reliable and efficient electrical connections in electronic circuits.

The measurement of insulation resistance is carried out by means of a megohmmeter – high resistance range ohmmeter. A general rule-of-thumb is 10 Megohm or more.

The parameter "Body/Shell Style" in electronic components refers to the physical design or shape of the outer casing or enclosure of the component. It is an important characteristic that helps in identifying and categorizing different types of components based on their form factor. The body/shell style can vary greatly depending on the specific component and its intended use, ranging from simple rectangular shapes to more complex designs with specific features for mounting, connecting, or protecting the internal components. Understanding the body/shell style of electronic components is crucial for proper installation, compatibility, and overall functionality within electronic circuits and systems.

Dielectric Withstanding Voltage (DWV) is a crucial parameter in electronic components that measures the maximum voltage a component can withstand without breaking down. It is also known as the insulation voltage or breakdown voltage. DWV is typically tested by applying a high voltage between the conductive parts of the component and the insulation material to ensure that the insulation can withstand the specified voltage without allowing current to flow through. This parameter is important for ensuring the safety and reliability of electronic components, especially in applications where high voltages are present. Components with a higher DWV rating are more suitable for use in high-voltage environments and applications.

In electronic components, the "Contact Pattern" refers to the arrangement and design of the contact points on a component, such as a connector or a switch. The contact pattern determines how electrical connections are made between the component and other devices in a circuit. It includes the number, size, spacing, and configuration of the contact points, which can vary depending on the specific application and requirements of the component. A well-designed contact pattern is crucial for ensuring reliable and efficient electrical connections, as it affects factors such as signal integrity, power transmission, and durability of the component. Manufacturers carefully engineer contact patterns to meet the desired performance specifications and standards for the component's intended use.

Mating Contact Row Spacing refers to the distance between the centerlines of adjacent rows of mating contacts on an electronic component or connector. This parameter is crucial for ensuring proper alignment and connection between mating components. The spacing is typically specified in millimeters or inches and plays a significant role in determining the overall size and layout of the electronic system. It is important to adhere to the specified mating contact row spacing to ensure compatibility and reliable performance of the electronic components.

Contact Finish Thickness refers to the measurement of the layer of conductive material applied to the surfaces of electrical contacts in electronic components. This thickness is critical as it influences the electrical conductivity, solderability, wear resistance, and overall performance of the connection. The materials used for the contact finish can include gold, silver, or other metals, and the specified thickness is designed to ensure reliable operation over the component's lifespan.

Plating thickness in electronic components refers to the measurement of the thickness of the metal plating applied to various surfaces of the component. This plating is typically done to enhance the component's conductivity, corrosion resistance, and solderability. The plating thickness is an important parameter as it directly affects the performance and reliability of the electronic component. Manufacturers specify the required plating thickness to ensure that the component meets the desired electrical and mechanical properties for its intended application. Testing and quality control measures are often employed to verify that the plating thickness meets the specified requirements.

The Material Flammability Rating is a parameter used to indicate the flammability characteristics of materials used in electronic components. It is typically measured according to standards such as UL94, which classifies materials into different categories based on their flammability properties. The rating helps in assessing the fire safety of electronic devices and components, as materials with higher flammability ratings are more resistant to ignition and combustion. Manufacturers often specify the Material Flammability Rating of their components to ensure compliance with safety regulations and standards. It is important to consider this parameter when designing and selecting electronic components to minimize fire hazards and ensure the overall safety of the end product.

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