Spectrum Analyzer and Signal Analyzer Results You Can Trust

To get reliable results, you need a spectrum analyzer that you can trust, whether you need deep-dive measurements for solving tough problems in spectrum analysis research and development (R&D) or quick and simple measurements for manufacturing.

  • Easily troubleshoot your signal analysis with one-button measurements in Keysight RF spectrum analyzers and the broadest set of application-specific software for industries such as 5G, IoT, automotive, and more
  • Get spectrum analysis results you can trust built on proven measurement science and a commitment to measurement integrity — whether you are optimizing your test for performance or throughput
  • Achieve greater longevity of your spectrum analysis test assets with upgradeable features, performance, and code compatibility

Spectrum Analyzer Basics

Learn how to use a spectrum analyzer and the fundamentals of frequency-domain measurements. You will also learn what problems are solved using a spectrum analyzer, the differences between a spectrum analyzer and an oscilloscope, and how to make RF noise measurements. 

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Spectrum analyzer

Get the Most Out of Your RF Spectrum Analyzer

Managing interference in an increasingly wireless world requires a magic touch with spectrum analysis efficiency. Spectral constraints translate to cumbersome testing. Cut through the complexity with powerful hardware and software that help you overcome interference challenges.

Learn how to maximize efficiency with a spectrum analyzer and overcome today's challenges. There is a frequency analyzer for every need. It's easy to set up, and it's hard to beat.

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Related use cases

How to Measure Signal Quality in 5G Private Networks

How to Measure Signal Quality in 5G Private Networks

Measuring 5G private network base station transmitter signal quality requires a high-frequency and wide-bandwidth test system that can address excessive path loss, wideband noise, and frequency errors with minimum impact on the EVM test results. Learn how to measure accurate signal quality in your 5G private network base station transmitters for your 5G new radio (NR) frequency range 1 (FR1) and FR2 applications.
How to Measure Noise Figure Using the Y-Factor Method

How to Measure Noise Figure Using the Y-Factor Method

Measuring noise figure requires characterizing a receiver and its ability to detect weak incoming signals in the presence of self-generated noise. Learn how to use the Y-factor method to conduct noise figure and gain measurements.
How to Test Time of Flight (ToF) of UWB Devices

How to Test Time of Flight (ToF) of UWB Devices

Validating ultra-wideband (UWB) devices requires time-of-flight measurements to ensure that the DUT reports signal flight time as expected. Learn how to enable accurate proximity calculations between UWB devices.
How to Simulate Interference for Automotive Radar Testing

How to Simulate Interference for Automotive Radar Testing

Performing in-depth automotive radar module interference immunity testing requires the ability to simulate various types of interference signals. Learn how to simulate radar targets and interference signals in the lab to effectively test your radar modules.
How to Locate Last Mile Interference

How to Locate Last Mile Interference

Locating the source of interference in last-mile testing requires direction-finding techniques, such as manual signal triangulation. Learn how to use a directional antenna to hunt last-mile interference in the field.
How to Monitor 5G Field Interference

How to Monitor 5G Field Interference

Identifying in-band and out-of-band interference requires real-time spectrum analysis and signal-capture capabilities. Learn how to capture elusive, intermittent signals and interference using real-time spectrum analysis.

Featured Signal Analysis (Spectrum Analysis) Resources

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Frequently Asked Questions – Signal Analyzers (Spectrum Analyzers)

spectrum analyzer measures the magnitude of an input signal versus its frequency over the full frequency range of the instrument to determine the power of signals. Spectrum analyzers enable tests like noise figure and signal-to-noise ratio (SNR) to characterize the performance of a device and its contribution to overall system performance. For more information, refer to this Spectrum Analysis Basics application note for more information.

signal analyzer measures both the magnitude and phase of an input signal at a single frequency. A signal analyzer combines the superior dynamic range of a swept tuned spectrum analyzer with vector signal analyzer (VSA) capabilities and enables in-channel measurements like error vector magnitude (EVM) that requires both magnitude and phase information.

Spectrum analyzers are used in a wide range of applications across various industries. Spectrum analyzers are important for analyzing and characterizing radio frequency (RF) signals in wireless communication systems, including Wi-Fi and cellular networks. Other applications include electronic design and testing, broadcasting and telecommunications, and aerospace and defense.

Spectrum analyzers measure the magnitude of an input signal versus signal frequency. Signal analyzers measure both the magnitude and phase of an input signal at a single frequency. Refer to this Spectrum Analyzer and Signal Analyzer technical overview for more information.

Our normal frame of reference is time. We note when certain events occur. This includes electrical events. An oscilloscope enables you to view the instantaneous value of a particular electrical event (or some other event converted to volts through an appropriate transducer) as a function of time. In other words, we use the oscilloscope to view the waveform of a signal in the time domain. Fourier theory tells us any time-domain electrical phenomenon consists of one or more sine waves of appropriate frequency, amplitude, and phase. In other words, it is possible to transform a time-domain signal into its frequency-domain equivalent. Spectrum analyzers and signal analyzers perform measurements in the frequency domain to measure energy at each particular frequency.

A complex signal in the time domain looks vastly different than in the frequency domain. The time-domain measurement shows an impure sine wave. Without measuring in the frequency domain, the source and frequency of the second harmonic remain unknown. A spectrum analyzer uncovers sources of interference by displaying the spectral components independently. The time-domain still provides useful information, such as the pulse rise and fall times of a signal, but the frequency domain allows you to determine the harmonic content of a signal, such as out-of-band emissions and distortion. For more information refer to this blog: Spectrum Analysis Basics, Part 1 – What is a Spectrum Analyzer?

A real-time spectrum analyzer first gathers data in the time domain and then translates it into the frequency domain by means of the Fast Fourier Transform (FFT). A real-time spectrum analyzer captures transient and fast signals quickly.

There are two broad categories of spectrum analyzers: swept-tuned analyzers and real-time analyzers. Modern spectrum analyzers use digital signal processing to provide additional measurement capability and let you interpret measurement results much more easily. Both swept-tuned and real-time spectrum analyzers display amplitude versus frequency. How they process and display this information, however, varies with the specific type of analyzer. A real-time spectrum analyzer displays the energy at all frequency components simultaneously. A swept-tuned spectrum analyzer displays measurement results sequentially, in other words, not in ''real-time''. This is because a swept-tuned analyzer uses a single narrow filter that is tuned across a range of frequencies to produce a spectrum display. Learn more about the different types of spectrum analyzers here.

Keysight’s U9361 RCal receiver calibrator enables you to perform an accurate and reliable calibration for your spectrum analyzer / signal analyzers using the following steps:

  1. Connect the RCal to your signal analyzer via a high-power USB port.
  2. Connect the signal analyzer’s 10 MHz reference signal to the U9361 RCal’s Reference In port.
  3. Set the RCal options reference status as EXT (external).
  4. Connect RCal’s RF Out to RF In of the signal analyzer.
  5. The Keysight signal analyzer preconfigures the interface. The screen displays type of calibration, frequency range, attenuation range, and number of points.
  6. Connect the RCal’s RF Out to the point in the path where the device under test (DUT) is when you take your actual measurements.
  7. Click on “Calibrate checked rows” to initiate the receiver calibrator and the signal analyzer to generate correction data.
  8. Disconnect the RCal and reconnect the signal path. This action moves the measurement plane. The X-Series signal analyzer dynamically tracks your measurements and only applies corrections to the states where needed.

Read more about How to Calibrate a Spectrum Analyzer.

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