An impedance analyzer is an electronic instrument used to measure the impedance of electronic components and circuits across a range of frequencies. Impedance is a complex quantity that includes both resistance and reactance, and it is essential to characterize electronic components and circuits accurately.
The basic principle behind an impedance analyzer involves applying a known voltage or current signal across the device under test (DUT) and measuring the resulting current or voltage across the DUT. By analyzing the phase and amplitude of the voltage and current, the instrument can calculate the complex impedance.
Here's a general overview of how an impedance analyzer works:
Signal Generation: The impedance analyzer generates a sinusoidal AC signal with a known frequency. This signal is usually swept over a range of frequencies to obtain the impedance response over a broad spectrum.
Bridge Circuit: The analyzer typically uses a bridge circuit configuration. The bridge circuit compares the impedance of the DUT to a reference impedance. The bridge circuit is balanced when the impedance of the DUT and the reference impedance are equal, resulting in minimum signal output.
Measurement: The balanced bridge output is then fed to a detector circuit, which measures the amplitude and phase difference between the applied signal and the response signal across the DUT.
Impedance Calculation: Using the measured amplitude and phase information, the impedance analyzer performs complex mathematical calculations, usually in polar or rectangular form, to determine the impedance of the DUT at the specific frequency.
Frequency Sweep: The impedance analyzer continues sweeping the frequency range and making measurements to create an impedance vs. frequency plot, often displayed as a Bode plot or Nyquist plot.
Data Presentation: The impedance analyzer presents the measured data either on a built-in display or outputs it to a computer for further analysis and visualization.
Different types of impedance analyzers may have additional features, such as DC bias capabilities for measuring components under bias conditions or more advanced analysis tools for characterizing complex circuits.
It's worth noting that impedance analyzers come in various forms, such as LCR (Inductance, Capacitance, Resistance) meters, vector network analyzers (VNAs), and impedance analyzers designed for specific applications like bio-impedance measurements. Each type has its own set of capabilities and use cases.