Panasonic Electric Works ARS10Y4H

In electronic components, the term "Mount" typically refers to the method or process of physically attaching or fixing a component onto a circuit board or other electronic device. This can involve soldering, adhesive bonding, or other techniques to secure the component in place. The mounting process is crucial for ensuring proper electrical connections and mechanical stability within the electronic system. Different components may have specific mounting requirements based on their size, shape, and function, and manufacturers provide guidelines for proper mounting procedures to ensure optimal performance and reliability of the electronic device.

The "Mounting Type" in electronic components refers to the method used to attach or connect a component to a circuit board or other substrate, such as through-hole, surface-mount, or panel mount.

The operating temperature is the range of ambient temperature within which a power supply, or any other electrical equipment, operate in. This ranges from a minimum operating temperature, to a peak or maximum operating temperature, outside which, the power supply may fail.

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.

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.

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

Termination in electronic components refers to the practice of matching the impedance of a circuit to prevent signal reflections and ensure maximum power transfer. It involves the use of resistors or other components at the end of transmission lines or connections. Proper termination is crucial in high-frequency applications to maintain signal integrity and reduce noise.

An ECCN (Export Control Classification Number) is an alphanumeric code used by the U.S. Bureau of Industry and Security to identify and categorize electronic components and other dual-use items that may require an export license based on their technical characteristics and potential for military use.

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, "Depth" typically refers to the measurement of the distance from the front to the back of the component. It is an important parameter to consider when designing or selecting components for a project, as it determines how much space the component will occupy within a circuit or device. The depth of a component can impact the overall size and layout of the circuit board or enclosure in which it will be installed. It is usually specified in millimeters or inches and is crucial for ensuring proper fit and functionality within the intended application.

In electronic components, the parameter "Frequency" refers to the rate at which a signal oscillates or cycles within a given period of time. It is typically measured in Hertz (Hz) and represents how many times a signal completes a full cycle in one second. Frequency is a crucial aspect in electronic components as it determines the behavior and performance of various devices such as oscillators, filters, and communication systems. Understanding the frequency characteristics of components is essential for designing and analyzing electronic circuits to ensure proper functionality and compatibility with other components in a system.

"Termination style" in electronic components refers to the method used to connect the component to a circuit board or other electronic devices. It determines how the component's leads or terminals are designed for soldering or mounting onto the circuit board. Common termination styles include through-hole, surface mount, and wire lead terminations.Through-hole components have leads that are inserted through holes in the circuit board and soldered on the other side. Surface mount components have flat terminals that are soldered directly onto the surface of the circuit board. Wire lead terminations involve attaching wires to the component for connection.The choice of termination style depends on factors such as the type of component, the manufacturing process, and the space available on the circuit board. Different termination styles offer various advantages in terms of ease of assembly, reliability, and space efficiency in electronic designs.

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.

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.

Contact Current (DC) - Max is a parameter in electronic components that specifies the maximum amount of direct current (DC) that can safely flow through the contact or connection point without causing damage or failure. This parameter is crucial for ensuring the reliability and longevity of the component, as exceeding the maximum contact current rating can lead to overheating, arcing, or even permanent damage. Designers and engineers must carefully consider this specification when selecting components for a circuit to prevent potential issues and ensure proper functionality. It is important to adhere to the manufacturer's guidelines and specifications to avoid any potential risks associated with exceeding the maximum contact current rating.

The "Max Current Rating" parameter in electronic components refers to the maximum amount of electrical current that the component can safely handle without being damaged. It is an important specification to consider when designing or selecting components for a circuit, as exceeding the maximum current rating can lead to overheating, malfunction, or even permanent damage to the component. The max current rating is typically provided in amperes (A) and is determined by the component's internal construction, materials used, and thermal characteristics. It is crucial to ensure that the current flowing through the component does not exceed this specified limit to maintain the component's reliability and longevity.

In electrical engineering, impedance is the opposition to alternating current presented by the combined effect of resistance and reactance in a circuit.

"Throw Configuration" is a term commonly used in the context of switches and relays in electronic components. It refers to the number of positions or states that the switch or relay can be set to. For example, a single-throw (ST) configuration means the switch has only one position, while a double-throw (DT) configuration means the switch has two positions.The throw configuration is important because it determines the versatility and functionality of the switch or relay. Different applications may require different throw configurations to control the flow of current or signals effectively. Understanding the throw configuration of a component is crucial for proper installation and operation within an electronic circuit.

The parameter "Max Voltage Rating (DC)" in electronic components refers to the maximum direct current (DC) voltage that the component can safely handle without being damaged. This rating is crucial for ensuring the proper functioning and longevity of the component within an electrical circuit. Exceeding the maximum voltage rating can lead to breakdown or failure of the component, potentially causing damage to the entire circuit. It is important to carefully consider and adhere to the specified max voltage rating when designing or working with electronic circuits to prevent any potential risks or malfunctions.

A page on a website that allows users to communicate with the site owner. The page has fields for filling in name, address and type of comment. On most company websites, email and mailing addresses are also included; however, the contact form provides an immediate, convenient way for users to ask the company questions.

In electronic components, the parameter "Relay Type" refers to the specific classification or categorization of a relay based on its design, functionality, and application. Relays are electromechanical devices that are used to control the switching of circuits by opening or closing contacts in response to an electrical signal. The relay type typically indicates the specific characteristics of the relay, such as its switching mechanism (e.g., electromagnetic, solid-state), contact configuration (e.g., SPST, DPDT), operating voltage, current rating, and intended use (e.g., power relays, signal relays, automotive relays). Understanding the relay type is important for selecting the right relay for a particular application to ensure proper functionality and reliability.

The time interval between the instant of the occurrence of a specified input condition to a system and the instant of completion of a specified operation.

Coil voltage refers to the electrical potential difference that is applied across the coil of an electromechanical device, such as a relay or a solenoid. This voltage is essential for energizing the coil, creating a magnetic field that enables the device to perform its intended function, such as opening or closing contacts. The coil voltage is specified by the manufacturer and varies depending on the design and application of the component, commonly available in standard values like 5V, 12V, 24V, and others. Proper selection of coil voltage is crucial for optimal performance and longevity of the device.

There are 2 different types of 'coil'; one has copper on it (IUD) and the other contains hormone (Mirena IUS). Both are over 99% effective at protecting against pregnancy.

The maximum switching voltage of a relay is the maximum voltage that can be across the contacts whether the relay is open or closed. Operating a relay with high voltages present can cause arcing, and this in turn erodes the contacts and eventually degrades contact performance.

A current coil is basically a coil, such as, a wire wrapped around an electrical conductor.

In telecommunication, release time is the time interval for a circuit to respond when an enabling signal is discontinued

Contact (DC) Max Rating R Load refers to the maximum direct current (DC) load that an electronic component, typically a relay or switch, can handle without risk of damage or failure. This rating indicates the highest permissible current that can pass through the contacts while maintaining reliable operation. It is crucial for ensuring the safety and longevity of the component in circuit applications that involve direct current. Exceeding this rating can lead to overheating, arc formation, or contact welding.

Must Operate Voltage is the minimum voltage level at which an electronic component or device is guaranteed to function correctly. Below this threshold, the component may experience performance issues, erratic behavior, or complete failure to operate. It is a critical specification for ensuring reliable operation in various applications where voltage variations can occur.

Power consumption is the amount of input energy (measured in watts) required for an electrical appliance to function. This is opposed to power output which is a measure of the level of performance, of a heat pump for example.

Must Release Voltage is the minimum voltage level that an electronic component, such as a relay or circuit breaker, requires to safely disengage or reset its mechanical operation. This parameter ensures that the component can reliably return to a non-energized state when power is removed or when a control signal goes low. It is an important specification for ensuring proper operation and safety in electronic circuits where the component may be exposed to fluctuating voltages.

Contact/Output Supply Type is a parameter used to describe the type of connection or output supply required for an electronic component to function properly. This parameter specifies the specific type of contact or supply needed for the component to receive power or transmit signals. It can include details such as the number of pins, voltage levels, current requirements, and communication protocols. Understanding the Contact/Output Supply Type is crucial for selecting compatible components and ensuring proper functionality within an electronic system.

Relay action refers to the type of mechanical movement performed by a relay in response to an electrical signal. It typically describes how the relay transitions between its open and closed states to either allow or interrupt the flow of current in a circuit. Relay action can be classified as normally open or normally closed, indicating the default state of the relay contacts before any current is applied. The speed and responsiveness of this action can significantly affect the performance of the overall circuit in which the relay is used.

The parameter "Coil Voltage (DC)" in electronic components refers to the voltage required to energize the coil of an electromagnetic device, such as a relay or a solenoid, when using direct current (DC) power. This voltage is necessary to create a magnetic field within the coil, which in turn activates the component to perform its intended function. The specified coil voltage must match the power supply voltage to ensure proper operation of the component. It is important to carefully select a component with the correct coil voltage rating to prevent damage and ensure reliable performance in electronic circuits.

Coil/Input Supply Type refers to the voltage and current specifications required to operate the coil in electromagnetic components such as relays and solenoids. This parameter indicates whether the component is designed to operate with AC or DC voltage sources and specifies the nominal voltage level for optimal performance. Understanding the Coil/Input Supply Type is essential for ensuring proper operation and compatibility with circuit designs.

VSWR stands for Voltage Standing Wave Ratio, and it is a measure of how efficiently radio frequency (RF) power is transmitted from a source, such as a transmitter, to a load, such as an antenna, through a transmission line. It is a dimensionless ratio that compares the maximum voltage in a standing wave pattern to the minimum voltage in that pattern along the transmission line. A VSWR value of 1 indicates perfect impedance matching, meaning all the power is being efficiently transferred without any reflections. Higher VSWR values indicate a mismatch in impedance, which can lead to power loss, signal degradation, and potential damage to components. VSWR is an important parameter in RF systems to ensure optimal performance and signal integrity.

Insertion Loss (dB) is a parameter used to measure the amount of signal loss that occurs when a component is inserted into a transmission line or circuit. It is typically expressed in decibels (dB) and represents the difference in signal power before and after the insertion of the component. A higher insertion loss value indicates greater signal attenuation or reduction in signal strength. Insertion loss is an important consideration in electronic components such as filters, amplifiers, and connectors, as it can impact the overall performance and efficiency of a system. Minimizing insertion loss is often a key design goal to ensure optimal signal integrity and transmission quality.

Input Power-Max (CW) is a parameter used to specify the maximum continuous wave power that an electronic component can handle without being damaged. This parameter is crucial in determining the power handling capability of the component under continuous wave operation. It is typically measured in watts and provides important information for designing circuits and systems to ensure that the component operates within its safe power limits. Exceeding the specified Input Power-Max (CW) can lead to overheating, degradation, or even permanent damage to the component.

The parameter "Dielectric Strength Between Open Contacts" in electronic components refers to the maximum voltage that can be applied across open contacts without causing electrical breakdown or arcing. It is a measure of the insulation capability of the material between the contacts. When the dielectric strength is exceeded, the insulating material may break down, leading to a short circuit or other electrical issues. This parameter is important in ensuring the reliability and safety of electronic components, especially in high-voltage applications where maintaining proper insulation is critical. Manufacturers provide dielectric strength specifications to help designers and engineers select components that can withstand the required voltage levels without failure.

Input Switching Control Type refers to the method or mechanism used to control the switching of inputs in electronic components such as switches, relays, or multiplexers. This parameter determines how the selection of different input channels is managed within the component. Common types of input switching control include manual control, where a user physically selects the input channel, and automatic control, where the switching is done based on predetermined criteria or signals. The choice of input switching control type can impact the functionality, flexibility, and ease of use of the electronic component in various applications.

The parameter "Dielectric Strength Between Coil and Contacts" in electronic components refers to the maximum voltage that can be applied between the coil and the contacts without causing electrical breakdown or insulation failure. It is a critical specification that indicates the insulation capability of the component and its ability to withstand high voltage levels. A higher dielectric strength value indicates better insulation properties and increased reliability in preventing electrical arcing or short circuits between the coil and contacts. This parameter is important in ensuring the safe and reliable operation of the electronic component in various applications where high voltages may be present.

Switching current refers to the maximum current that an electronic component, such as a transistor or relay, can handle when transitioning between its on and off states. It is a critical parameter that affects the performance and reliability of the component during switching operations. Exceeding the specified switching current can lead to overheating, damage, or failure of the device. Understanding switching current is essential for designing circuits that operate safely and efficiently.

Switching time in electronic components refers to the time it takes for a device to change its state from one condition to another. It is a crucial parameter in determining the speed and efficiency of electronic circuits. The switching time is typically measured as the time taken for a signal to transition between specified voltage levels, such as from high to low or vice versa. Faster switching times indicate a more responsive and high-performance component, while slower switching times can lead to delays and inefficiencies in the circuit operation. Overall, understanding and optimizing the switching time of electronic components is essential for designing reliable and efficient electronic systems.

In electronic components, "Body Height" refers to the vertical dimension of the component's physical body or package. It is the measurement from the bottom of the component to the top, excluding any leads or terminals. Body Height is an important parameter to consider when designing circuit boards or enclosures to ensure proper fit and clearance. It is typically specified in datasheets or technical drawings provided by the component manufacturer. Understanding the Body Height of electronic components is crucial for proper placement and integration within a circuit or system.

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