STMicroelectronics BTA26-800CW

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

In electronic components, the parameter "Material" refers to the substance or material used in the construction of the component. The choice of material is crucial as it directly impacts the component's performance, durability, and other characteristics. Different materials have varying properties such as conductivity, resistance to heat, corrosion resistance, and mechanical strength, which determine how the component functions in a circuit. Common materials used in electronic components include metals like copper and aluminum, semiconductors like silicon, insulators like ceramics and plastics, and various alloys. Selecting the appropriate material is essential for designing reliable and efficient electronic components.

In electronic components, the parameter "Shape" refers to the physical form or outline of the component. It describes the external appearance of the component, including its dimensions, size, and overall structure. The shape of an electronic component can vary widely depending on its function and design requirements. Common shapes include rectangular, cylindrical, square, and circular, among others. The shape of a component is an important consideration in the design and layout of electronic circuits, as it can impact factors such as space utilization, heat dissipation, and ease of assembly.

Package Cooled refers to a type of thermal management in electronic components where the device packaging is designed to dissipate heat efficiently. This involves integrating cooling features such as heat sinks or specialized materials that enhance heat transfer away from the component. The goal is to maintain optimal operating temperatures and improve reliability and performance of the electronic device. It is commonly used in high-power applications where excessive heat generation can affect functionality.

Material Finish in electronic components refers to the surface treatment applied to the component to enhance its performance, durability, and reliability. The finish can protect the component from environmental factors such as moisture, corrosion, and mechanical stress. Common material finishes include gold plating, tin plating, silver plating, and organic coatings. The choice of material finish depends on the specific requirements of the application, such as conductivity, solderability, and cost-effectiveness. Proper material finish selection is crucial to ensure the long-term functionality and quality of electronic components.

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.

The "JESD-609 Code" in electronic components refers to a standardized marking code that indicates the lead-free solder composition and finish of electronic components for compliance with environmental regulations.

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

Terminal Finish refers to the surface treatment applied to the terminals or leads of electronic components to enhance their performance and longevity. It can improve solderability, corrosion resistance, and overall reliability of the connection in electronic assemblies. Common finishes include nickel, gold, and tin, each possessing distinct properties suitable for various applications. The choice of terminal finish can significantly impact the durability and effectiveness of electronic devices.

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.

The attachment method in electronic components refers to the technique used to connect a component to a circuit board or assembly. This can include methods such as soldering, bonding, or using connectors. The choice of attachment method can affect the reliability, performance, and manufacturability of the electronic device. Different methods may be suited for specific applications based on factors like mechanical stress, thermal conductivity, and ease of assembly.

The parameter "Height Off Base (Height of Fin)" in electronic components refers to the distance between the base of the component and the top of any fins or protrusions on the component. This measurement is important for determining the overall dimensions and clearance requirements of the component within a circuit or system. It helps in ensuring proper fit and alignment of the component during installation and assembly. Manufacturers provide this specification to assist designers and engineers in selecting the appropriate components for their applications based on the available space and mechanical constraints.

Thermal Resistance @ Forced Air Flow is a measure of how effectively an electronic component can dissipate heat when subjected to airflow. It quantifies the resistance to heat transfer from the component to the surrounding air in scenarios where forced ventilation is employed, such as with fans. This parameter is crucial for evaluating thermal performance, as it impacts the component's operating temperature and reliability under conditions of active cooling. Lower thermal resistance values indicate better heat dissipation capabilities, essential for maintaining optimal performance in high-power applications.

Case Connection refers to the method by which an electronic component's case or housing is connected to the electrical circuit. This connection is important for grounding purposes, mechanical stability, and heat dissipation. The case connection can vary depending on the type of component and its intended application. It is crucial to ensure a secure and reliable case connection to maintain the overall performance and safety of the electronic device.

Trigger Device Type is a parameter in electronic components that refers to the type of device or mechanism used to initiate a specific action or function within the component. This parameter specifies the specific trigger device, such as a sensor, switch, or signal input, that is required to activate or control the operation of the component. Understanding the trigger device type is crucial for proper integration and operation of the electronic component within a larger system or circuit. By specifying the appropriate trigger device type, engineers and designers can ensure that the component functions correctly and responds to the intended input signals or conditions.

The Repetitive Peak Off-state Voltage (Vdrm) is a key parameter in electronic components, particularly in devices like thyristors and triacs. It refers to the maximum voltage that can be applied across the component when it is in the off-state without triggering it to turn on. This parameter is crucial for ensuring the proper functioning and reliability of the component in various circuit applications. It helps determine the voltage level at which the component can safely operate without experiencing unintended conduction. Designers need to consider the Vdrm rating to prevent damage to the component and maintain the overall performance of the circuit.

The parameter "Critical Rate of Rise of Off-State Voltage-Min" in electronic components refers to the minimum rate at which the off-state voltage of a device must rise in order to trigger a critical event, such as a breakdown or failure. This parameter is crucial for ensuring the reliable operation of the component under various conditions. It helps determine the maximum allowable rate of voltage increase that the component can withstand without experiencing detrimental effects. Manufacturers specify this parameter to guide engineers and designers in selecting and using the component within its safe operating limits to prevent damage or malfunction. Understanding and adhering to this parameter is essential for maintaining the performance and longevity of electronic devices.

The parameter "RMS On-state Current-Max" in electronic components refers to the maximum root mean square (RMS) current that the component can handle when it is in the on-state or conducting state. This specification is important for devices such as thyristors, triacs, and other semiconductor switches that are used to control power in various applications. Exceeding the maximum RMS on-state current rating can lead to overheating and potentially damaging the component. Designers must carefully consider this parameter to ensure the component operates within its specified limits for safe and reliable performance.

The parameter "Holding Current-Max" in electronic components refers to the maximum current required to maintain the component in its ON state once it has been triggered or turned on. This holding current is necessary to prevent the component from turning off unintentionally due to fluctuations in the input signal or other external factors. It is an important specification for components such as thyristors, triacs, and other semiconductor devices that require a continuous current to remain in the conducting state. Understanding the Holding Current-Max value is crucial for ensuring the reliable operation of the component within its specified parameters.

Thermal Resistance @ Natural refers to the ability of an electronic component to dissipate heat under natural convection conditions without forced airflow. It is measured in degrees Celsius per watt and represents the temperature rise of the component above the ambient temperature for each watt of power dissipated. This parameter is crucial for understanding how effectively a component can manage heat during operation, ensuring reliability and performance. Manufacturers provide this value to help designers assess thermal management strategies in circuit designs.

The parameter "DC Gate Trigger Current-Max" refers to the maximum current required to trigger the gate of a semiconductor device, such as a thyristor or a triac. This parameter specifies the maximum current that must be applied to the gate terminal to turn on the device reliably. Exceeding this maximum current may result in improper operation or damage to the component. It is an important parameter to consider when designing circuits that involve triggering these semiconductor devices, as it ensures proper functionality and reliability of the component.

The parameter "DC Gate Trigger Voltage-Max" refers to the maximum voltage required to trigger the gate of a semiconductor device, such as a thyristor or a triac. This voltage level is crucial for initiating the conduction state of the device, allowing current to flow through it. Exceeding this maximum voltage can lead to unintended triggering or damage to the component. Manufacturers specify this parameter to ensure proper operation and reliability of the device in various applications. Designers and engineers need to consider this specification when selecting and using these components in their circuits to prevent malfunctions and ensure optimal performance.

Power Dissipation at Temperature Rise refers to the maximum amount of power an electronic component, such as a semiconductor or resistor, can dissipate while maintaining a specified increase in temperature above its ambient environment. This parameter is crucial for ensuring the reliability and longevity of components, as excessive heat can lead to failure. It is typically expressed in watts and is determined by the thermal characteristics of the component and its cooling mechanisms. Proper management of power dissipation is essential for optimal performance in electronic circuits.

The parameter "Repetitive Peak Off-state Leakage Current-Max" in electronic components refers to the maximum amount of current that flows through the device when it is in the off-state and subjected to repetitive peak voltage stress. This parameter is important for determining the leakage current characteristics of the component, which can impact the overall performance and reliability of the circuit. A lower value for this parameter indicates better isolation and reduced power consumption in the off-state. Designers need to consider this parameter when selecting components for applications where minimizing leakage current is critical.

In electronic components, the parameter "Diameter" typically refers to the measurement of the width of a circular component, such as a resistor, capacitor, or inductor. It is a crucial dimension that helps determine the physical size and fit of the component within a circuit or on a circuit board. The diameter is usually measured in millimeters (mm) or inches (in) and is important for ensuring proper placement and soldering of the component during assembly. Understanding the diameter of electronic components is essential for selecting the right size for a specific application and ensuring compatibility with other components and the overall design of the circuit.