Description
Specifications Table
Product Material – High-quality PCB with copper traces
Grade – Laboratory/Research Grade
Application – Frequency response analysis, resonance testing, circuit tuning
Product Overview
The LCR Resonance Circuit with Built-in Sine Wave Oscillator is engineered for precision frequency analysis in laboratory settings. This circuit integrates a high-stability sine wave oscillator that generates clean, distortion-free signals across a wide frequency range, enabling accurate resonance testing of LCR components. The robust PCB construction with copper traces ensures minimal signal loss and superior thermal stability, making it ideal for demanding experimental conditions. The built-in oscillator eliminates the need for external signal sources, simplifying setup while maintaining professional-grade accuracy. Designed for durability, this circuit features corrosion-resistant components that withstand prolonged use in educational and research environments. Whether used for basic circuit tuning or advanced frequency response studies, this LCR resonance kit delivers consistent performance with minimal calibration requirements. The compact design allows easy integration into existing lab setups, while the intuitive layout enables quick component identification and modification. Perfect for applications requiring precise impedance matching and resonance characterization.
FAQs
1. What frequency range does this LCR resonance circuit support?
The circuit is designed to cover a broad frequency spectrum typically ranging from 20Hz to 20kHz, suitable for most standard LCR resonance experiments and frequency response analyses.
2. Can this circuit be used with external power supplies?
Yes, the circuit is compatible with standard DC power supplies in the 5V-12V range, though it includes its own built-in sine wave oscillator that operates efficiently within this voltage window.
3. What alternatives exist for testing higher frequency ranges?
For applications requiring testing beyond 20kHz, specialized RF resonance circuits or vector network analyzers would be more appropriate, though these require additional expertise to operate.
4. How should this circuit be stored when not in use?
Store the circuit in a dry, dust-free environment at room temperature, preferably in an anti-static bag or container to prevent component degradation from moisture or electrostatic discharge.
5. Are the components in this circuit replaceable if damaged?
The modular design allows for individual component replacement, though we recommend using identical specifications for resistors, capacitors, and inductors to maintain original performance characteristics.
