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EXA Signal Analyzer / Multi-touch / 10 Hz to 26.5 GHz
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Unit only ships within China.
Unit ships worldwide.
USD 45,714.55 Save 65%
|526||Frequency range, 10 Hz to 26.5 GHz|
|B40||Analysis bandwidth, 40 MHz|
|CR3||Connector rear, second IF output|
|CRP||Connector, programmable rear IF output|
|DP2||DIGITAL PROCESSOR, 2 GB CAPTURE MEMORY|
|EA3||ELECTRONIC ATTENUATOR, 3.6GHZ|
|EDP||ENHANCED DISPLAY PACKAGE|
|EMC||Basic EMC functionality|
|EP5||ENHANCED PHASE NOISE PERFORMANCE II (STANDARD)|
|ESC||External source control|
|FP2||Fast power, up to 40 MHz bandwidth|
|FSA||Fine resolution step attenuator|
|MPB||Microwave preselector bypass|
|NF2||Noise floor extension, instrument alignment|
|P26||Preamplifier, 26.5 GHz|
|PFR||PRECISION FREQUENCY REFERENCE|
|SSD||ADDITIONAL REMOVABLE SOLID STATE DRIVE, W7X|
|TDS||Time Domain Scan - requires N6141C and DP2 or B40|
|YAS||Y-AXIS SCREEN VIDEO OUTPUT|
Fast, Flexible General-Purpose Signal Analysis
When enhancing a product and improving test throughput, your general-purpose signal analyzer should be ready for a wide range of challenging requirements. The fast, flexible N9010B EXA Signal Analyzer addresses diverse needs with a solid mix of speed and performance and the versatility of PathWave X-Series measurement applications.
- Save test time in your spurious response measurements with the fast sweep capability
- Get the most cost-effective analysis for millimeter-wave measurements
- Measure small signals in the presence of large ones with best-in-class level accuracy, displayed average noise level (DANL), and third order intermodulation (TOI) distortion
- Perform power measurements quickly at discrete frequency points with list-sweep mode
- Simplify testing with PathWave X-Series measurement applications
Ready To Get Started?
What You Get
- Keysight N9010B-526 Spectrum Analyzers
- Accessories only included if shown in the pictures
- Calibration certificate only included if shown in the pictures
What You Can Add
- KeysightCare Assured
- Fresh Calibration
- Calibration Plan
|Keysight New||Keysight Premium Used||Keysight Used|
|Savings||None||Up to 70%||Up to 90%|
|Condition||New||Like New||Working Condition ¹|
|Warranty||1 to 5 Years ²||Like New||90 Days Warranty|
Learn more about Keysight Premium Used Here
Customization is generally possible with our Keysight Premium Used equipment. The majority of our Keysight Premium Used equipment can be configured just the way you need it. Options can be added at additional cost.
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Keysight Premium Used equipment typically comes with the same accessories and warranty as new products.
We currently only offer those accessories which are part of the listing. Other accessories can be purchased separately at extra cost with your purchase of a Keysight Used or Keysight Premium Used unit.
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A signal analyzer is a device used to test and measure electronic signals. Types of signals can vary, including voltage, current, and radiofrequency. Signal analyzers vary in their capabilities and features, depending on the application. There are many types of signal analyzers, but the most common type is an oscilloscope. Other types include spectrum analyzers, network analyzers, and signal generators.
An oscilloscope is a device used when designing electronic systems that allows a signal to be viewed as a waveform. A spectrum analyzer measures the amplitude and frequency of signals over a specific period of time. A network analyzer analyzes circuits without having access to their design details; this can be helpful when there is a delay between creating a circuit and testing it. A signal generator generates signals which are then used by other devices.
There are many uses for a signal analyzer, depending on the type of device and features available. Some standard capabilities include:
Generating and analyzing signals
Magnifying and analyzing large signals
Displaying waveforms of varying types
Displaying the full frequency range of a signal, including visual representations of different frequencies and noise levels
A signal analyzer analyzes signals that have already been generated, whereas a spectrum analyzer is used to discover frequencies or actually generate frequencies itself.
A spectrum analyzer performs real-time spectrum analysis and measures instantaneous power or peak power, voltage, or current, depending on the type of signal being analyzed. It is also often used to monitor electromagnetic interference in circuits and devices.
On the other hand, a signal analyzer can only measure signals that are already present; it cannot be used to discover or analyze frequencies. Its purpose is to help the user identify electronic circuit problems and understand how the circuit is performing.
The main difference between a signal analyzer and an oscilloscope is that a signal analyzer analyzes the voltage of a signal over a specific period of time. In contrast, an oscilloscope extracts the timing information of a signal.
An oscilloscope is a type of signal analyzer used to measure voltage signals over time. It has various features, including analog and digital functions, advanced triggering capabilities, and connectivity options. It is used to analyze signals from many different sources, such as time-domain signals, frequencies from radiofrequencies, or extremely low-frequency sources.
A signal analyzer is used to analyze signals that have already been generated. A signal analyzer is often used to monitor electromagnetic interference in circuits and devices, whereas an oscilloscope can only measure signals that are already present.
A network analyzer is used to test the performance of wired or wireless networks by examining both transmitted and received signals. Unlike a signal analyzer, it performs advanced analysis of both transmitted and received signals. It is different from a signal analyzer because it performs a live, real-time, analysis of signals on the device under test. In contrast, a signal analyzer only analyzes data after the signal has been created.
A network analyzer can also perform analysis and detect problems that prevent a signal from reaching its destination. For example, it can detect issues with cabling, connectors, or faulty equipment. It can also help resolve RF spectrum and Wi-Fi issues, such as interference and signal loss.
A signal analyzer is used by engineers to identify problems in electronic circuits and to understand how a circuit is behaving; for example, monitoring electromagnetic interference between multiple signals or devices. This makes it useful for testing and debugging circuits that use radio signals or other powerful sources of potential interference.
An antenna's impedance refers to the way it responds to signals from specific frequencies. If you want to know what sort of wireless signal a device is sending, you should evaluate the antenna's impedance with a spectrum analyzer. The device would help you determine whether or not your antenna is being affected by noise, which can negatively impact performance.
To measure your antenna's impedance, you can attach a spectrum analyzer to the end of the coaxial cable connected to the back of your antenna. The device will then calculate the impedance being transmitted once it goes through your coaxial cable.
Phase noise is a type of signal that often disrupts or interferes with wireless communication. It is a problem for devices that operate in the wireless frequency spectrum. If phase noise is common across specific frequencies, it can drown out other signals.
There are many different types of phase noise, and each one can affect your wireless technology differently. A signal analyzer measures the phase noise across different frequencies. The device will help you to determine whether your intended wireless communication needs some sort of interference protection.
To measure your device's phase noise with a signal analyzer, you can attach the device to the input of your receiver. This will allow the signal analyzer to calculate how much phase noise is being sent through your wireless communication devices.
The return loss is the measurement of how much signal is reflected or wasted at a particular point. It is a measurement of how much energy is being lost in transmission. You can measure return loss with a spectrum analyzer which may enable you to improve the power and efficiency of your wireless connection.
If the return loss is too high, it could indicate power-management issues within your system. A signal analyzer can help you determine whether the return loss is too high, and help you find any hardware issues needing to be resolved. The device can notify you when your power-management settings fall below requirements for successful wireless communication.
To test a device’s return loss with a signal analyzer, plug the spectrum analyzer into the end of a coaxial cable connected to your intended transmitter. The device will determine how much signal is lost after it goes through the cable and exits to reach its intended recipient.
For additional information about how to use your spectrum analyzer to measure return loss, view “Features Resources” for a technical overview of a basic spectrum analyzer as well as an example of how to measure the return loss of an antenna.