L3 Narda-MITEQ SSM0618MC2MDA

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

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

Construction in electronic components refers to the design and materials used in the manufacturing of the components. It encompasses the physical structure, arrangement, and integration of various parts like substrates, conductors, and insulators. The construction impacts the performance, reliability, and thermal properties of the component, influencing how it interacts with electrical signals and other components in a circuit. Different construction techniques can also affect the size, weight, and cost of the electronic component.

The parameter "RF/Microwave Device Type" in electronic components refers to the specific type or category of devices designed to operate within the radio frequency (RF) and microwave frequency ranges. These devices are engineered to handle high-frequency signals and are commonly used in various applications such as wireless communication, radar systems, satellite communication, and more. Examples of RF/Microwave device types include amplifiers, filters, mixers, oscillators, antennas, and transceivers. Understanding the RF/Microwave device type is crucial for selecting the appropriate component that meets the requirements of a particular RF system or application.

VSWR-Max stands for Voltage Standing Wave Ratio Maximum, which is a parameter used in electronic components, particularly in RF and microwave applications. It measures how effectively power is transmitted from a source through a transmission line to a load, indicating the level of reflected power due to impedance mismatches. A lower VSWR-Max value signifies better impedance matching and higher efficiency, while a higher value indicates poor matching, leading to greater signal reflections and potential performance issues. Manufacturers specify VSWR-Max to help ensure components operate within acceptable limits for optimal functionality.

Characteristic impedance is a fundamental property of transmission lines and refers to the specific impedance that a transmission line presents to an electrical wave propagating along it. It is determined by the physical parameters of the transmission line, including its inductance and capacitance per unit length. When the line is terminated with a load that matches its characteristic impedance, maximum power transfer occurs, minimizing reflections and signal losses. In high-frequency applications, maintaining the characteristic impedance is crucial for signal integrity and performance.

LO Tunable refers to the ability of a local oscillator (LO) in electronic components, such as radio frequency (RF) circuits, to be adjusted or tuned over a specific frequency range. This adjustability allows the device to select different frequencies for signal processing, enabling better performance and flexibility in applications like mixers and signal converters. The tuning can be achieved through various means, such as variable capacitors, inductors, or digital tuning methods.

RF Input Frequency-Max refers to the maximum frequency of the radio frequency signal that an electronic component, such as an amplifier, filter, or receiver, can effectively process or handle. This parameter is crucial in determining the operating range of the component and ensures that it can operate efficiently without distortion or signal loss at higher frequencies. Exceeding the RF Input Frequency-Max can result in decreased performance, increased noise, or potential damage to the component.

RF Input Frequency-Min refers to the minimum frequency of the radio frequency signals that a component can effectively receive or process. It indicates the lower limit of the frequency spectrum within which the device operates correctly. This parameter is crucial for defining the range of RF applications, ensuring that the component can handle signals that fall within the specified frequency band without significant degradation of performance.

IF Frequency-Max refers to the maximum intermediate frequency at which a receiver or circuit can operate effectively. It is a crucial parameter in the design of radio frequency (RF) and communication systems, determining the upper limit of signal frequency processing before demodulation. This frequency influences the selectivity and sensitivity of receivers and is essential for ensuring proper filtering and signal integrity in various electronic applications.

IF Frequency-Min refers to the minimum intermediate frequency in electronic components, particularly in radio receivers and communication systems. It is the lowest frequency used in the processing of received signals after they have been mixed with a local oscillator signal. This parameter is critical for ensuring proper signal demodulation and minimizes interference from unwanted signals. The IF Frequency-Min is essential for achieving desired selectivity and performance in various applications such as superheterodyne receivers.

RF Output Frequency-Max refers to the maximum frequency at which a radio frequency (RF) component, such as an amplifier or oscillator, can effectively transmit or generate signals. This parameter is crucial in determining the operational range and performance of RF devices. Exceeding this frequency can lead to reduced efficiency, increased distortion, or complete failure to operate as intended. Understanding this parameter helps engineers design systems that operate within the required frequency bands for communication and signal processing applications.

The parameter RF Output Frequency-Min refers to the minimum frequency at which a device, such as a radio frequency generator or transmitter, can effectively produce an output signal. This value is critical for applications that require signal generation within specific frequency ranges. Operating below this minimum frequency may result in degraded performance or complete inability to generate a usable signal. The parameter is essential for ensuring compatibility with other components in a circuit or system.