1. Download the firmware upgrade package from the official website.
2. Unzip the ADS format file and save it to the root directory of the U disk.
3. Insert the U disk into the USB Host port and navigate to System > Service > Upgrade on the device to locate the ADS file on the USB drive.
4. Confirm the analyzer will automatically perform the firmware upgrade.

Click to Download the complete Document

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IQ acquisition is similar to zero-span measurement in Swept SA, where the input signal is displayed as I/Q data results. It is commonly used for measuring digital modulated signals and supports exporting IQ data to txt files for users to perform data demodulation and analysis. The IQA window presents the I and Q signal waveforms, depicting the voltage changes over time. The I signal is represented by the yellow trace, while the Q signal is represented by the purple trace. I/Q views provided in spectrum measurements enables users to examine complex components of the same signal without the need to modify settings or measurements.

1.1 Amplitude

Configuring the amplitude parameters of the analyzer makes the display of the measured signal visually appealing and minimizes measurement errors. By adjusting these parameters, the signal can be displayed in the current window in an easily observable format. Once the amplitude parameters have been modified, the measurement process will commence anew.

1.1.1  Ref Value

         The reference line may be positioned top, center or bottom of the marker by setting a reference value.1.2 Scale/Div

Configuring the unit for each vertical scale division in the logarithmic display can be done by either manually setting the value or enabling automatic scaling, which is determined by the measured results.

1.1.2  Attenuation

Based on the magnitude of the input signal, the user configures the corresponding RF front-end attenuator and amplifier to avoid distortion when presenting large input signals and reduce noise when dealing with small input signals.

1.2 Sweep

1.2.1 Sweep/Measure

The analyzer can be set to perform a single Scan/Measure or continuous Scan/Measure by selecting the ‘Single’ or ‘Continue’ mode.

1.2.2 Restart

Restarting the current scan or measurement is achieved by initiating a re-Scan/Measure, particularly if the scan parameters have been modified.

1.3 Meas Setup

Click on the ‘Measurement Settings’ menu and select appropriate averaging parameters, center frequency, measurement time, and sampling rate based on the specific parameters of the acquired IQ signal.

1.3.1 Avg|Hold Number

Averaging|Hold count N represents the counter when the trace type is set to ‘Average’. In a single measurement (Single) and any valid trace type set to ‘Average’, the scan will stop when the counter reaches N.

A higher (Average|Hold) count can reduce the influence of noise or other random signals, highlighting the stable characteristics of the signal.

1.3.2 Averaging

Enable or disable the averaging calculation option for measurement results.

1.3.3 Avg Mode

Choose the control type for the averaging function. This determines the averaging operation after reaching the specified data acquisition count (average count).

Options include:

      -Exponential (Exp): The measurement averages using a specified number of exponentially weighted averages. The average value is displayed at the end of each scan.

      – Repeat: The measurement resets the average counter each time the specified number of averages is reached.

1.3.4 Center Freq

Ensure that the set center frequency matches the frequency of the IQ signal, otherwise the IQ waveform will not be displayed properly.

1.3.5 Meas Time

Set the time for signal acquisition, which represents the recording duration of the waveform. Due to memory limitations, the maximum measurement time may decrease when using a higher sampling rate.

1.3.6 Sample Rate

Set the sampling rate for signal acquisition, indicating the number of IQ pairs collected per second. Choose an appropriate sampling rate based on the specific IQ signal to avoid distortion in the acquired IQ signal.

1.4 Operation Demonstration

1）Input the 16QAM signal through the RF port of SSA5000A.

2）Use the IQ Acquisition to observe the I/Q signal waveform of the signal:

(1)Click Mode/Meas→Spectrum Analyzer(SA)→IQ Acquisition→Replace/Add→OK.

(2) Click FREQ, configure the center frequency corresponding to the IQ signal.

(3) Click AMPTD, Adjust the reference level, the scale and measurement time to better display the I/Q waveform on the screen.

(4) Click Save/Recall, save IQ data as .txt file.

2. IF Output

The intermediate frequency (IF) output signal can be used for external signal processing and can be obtained via the ‘IF Out’ output connector on the instrument’s rear panel. Please note that the IF output is only useful in Zero Span.

The IF Out signal, centered at approximately 120MHz, is simply a down-converted version of the RF Input signal that is present at the tuned frequency. The bandwidth of the IF output signal is approximately 40MHz. Requires Option SSA5000-IFO.

2.1 Operation Demonstration

1）Input the RF signal to the RF port, and then output the IF signal through the IF Out connector on the rear panel.

2）Click FREQ, configure the center frequency corresponding to the RF signal and turn on the Zero Span mode.

3）Click Input/Output, turn on the IF Out function.

4）Use another spectrum analyzer to observe the IF signal. Configure the center frequency to 120MHz and the span to 50MHz.

IF Output when input an 1GHz RF signal

IF Output when input a 3.5 GHz NR signal

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The EMI toolkit has been tested with pulse repetition rate minimum of 20 Hz, but has not been tested below this.

Increased error is expected and therefore it is not recommended for use below 20 Hz.

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ESD events that occur near a sensitive RF circuit can cause:

• Complete loss of measurement capability. This can be verified visually. There may be no trace changes on the display when a known good signal is delivered to the input, etc..
• Increased amplitude measurement error. The additional error could cause the readings to be higher or lower than expected.. from 0.1 dB to 10’s of dB.
• Increased tracking generator/stimulus source error.

Instrument designers include ESD prevention and protection in their designs, but this can only minimize the risk of damage.

Here are some steps you can implement to further minimize ESD events when working with sensitive circuitry:

1. Maintain a relative humidity above 40%. Low humidity increases the likelihood of ESD events.
2. Short the center pin and outer shield of cables to neutralize any potential differences before connecting the cable to any sensitive input
3. Use proper ESD protection when working with input connectors or sensitive boards. Basic protection includes using a 1 MOhm resistor-isolated ESD wrist strap and ESD minimized work surfaces.
4. Always use properly grounded power outlets and power cords

You can learn more at https://www.esda.org/

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Click for tips on AM/FM Demodulation

Here are the specifications for the audio output:

• 3.5 mm Mono output.
• 16-ohm output impedance
• Output power of approximately 13 mW

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Check the datasheet for the product in question to find more information.

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It is useful for determining the physical location of breaks, dielectric degradation, and other issues in cabling, connectors, and adapters.

This technique utilizes a swept signal source to produce an output signal that covers a known frequency range. As the impedance of the cable/Device-Under-Test (DUT) changes, some of the swept energy is reflected back to the source. This reflected energy is measured and an inverse FFT (IFFT) of the data is used with the propagation velocity of the cable to calculate the physical distance from the source to the impedance difference.

The display shows the reflection coefficient (the ratio of complex amplitude of the reflected vs incident wave) on the X-axis vs. distance from the source:

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For best performance, use SMAs with SMAs and 3.5 mm connectors with 3.5 mm connectors. If you question the connection integrity, you can use connector gages to verify the proper pin and thread locations.

Proper cleaning of the mating surfaces with a lint-free swab and isopropyl alcohol is recommended as well as using a calibrated torque wrench.

For proper torque values of SIGLENT calibration kits, see the Mechanical Calibration Kit Datasheet

SMA connectors, like those shown below, have a plastic or foam insulator around the center conductor:

3.5 mm connectors have an air insulator:

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