SignalVu RF and vector signal analysis software combines the signal analysis engine of the RSA5000 Series real-time spectrum analyzer with that of the industry's leading digital oscilloscopes, making it possible for designers to evaluate complex signals without an external down converter. You get the functionality of a vector signal analyzer, a spectrum analyzer, and the powerful trigger capabilities of a digital oscilloscope - all in a single package. You can use SignalVu with an MSO/DPO5000, DPO7000, or DPO/DSA/MSO70000 Series digital oscilloscope to easily validate wideband designs and characterize wideband spectral events. Whether your design validation needs include wideband radar, high data rate satellite links, wireless LAN, WiGig IEEE 802.11ad, or frequency-hopping communications, SignalVu can speed your time-to-insight by showing you the time-variant behavior of these wideband signals.

Key features

• Trigger
  • Integrated RF signal analysis package lets you take full advantage of oscilloscope settings
  • Pinpoint? triggering offers over 1400 combinations to address virtually any triggering situation
• Capture
  • Direct observation of microwave signals without need of an external down converter
  • All signals up to the analog bandwidth of oscilloscope are captured into memory
  • Customize oscilloscope acquisition parameters for effective use of capture memory
  • FastFrame segmented memory captures signal bursts without storing the signal's off time
  • Supports RF, I and Q, and differential I and Q signals using the oscilloscope's 4 analog inputs
• Analyze
  • time-correlated, multidomain displays connect events in time, frequency, phase, and amplitude for quicker understanding of cause and effect when troubleshooting
  • Power measurements and signal statistics help you characterize components and systems: SEM, Multicarrier ACLR, Power vs. Time, CCDF, OBW/EBW, and Spur Search
  • WLAN spectrum and modulation transmitter measurements based on IEEE 802.11 a/b/g/j/p/n/ac standards (Opts. SV23, SV24, and SV25)
  • WiGig IEEE 802.11ad Spectral and modulation transmitter measurements (Opt. SV30)
  • Bluetooth® Transmitter Measurements based on Bluetooth SIG RF Specifications for Basic Rate and Low Energy. Some support of Enhanced Data Rate. (Option SV27)
  • LTE? FDD and TDD Base Station (eNB) Transmitter RF measurements (Option SV28)
  • Complete APCO Project 25 transmitter testing and analysis for Phase 1 (C4FM) and Phase 2 (TDMA) (Opt. SV26)
  • AM/FM/PM Modulation and Audio Measurements (Opt. SVA) for characterization of analog transmitters and audio signals
  • Settling Time Measurements, Frequency, and Phase (Opt. SVT) for characterization of wideband frequency-agile oscillators
  • Advanced Signal Analysis Suite (Opt. SVP) - Automated pulse measurements provide deep insight into pulse train behavior
  • General Purpose Digital Modulation Analysis (Opt. SVM) provides vector signal analyzer functionality
  • Flexible OFDM analysis (Opt. SVO) with support for 802.11a/g/j and WiMAX 802.16-2004 signals
  • Frequency offset control for analyzing baseband signals with near-zero intermediate frequencies (IF)
  • Tektronix OpenChoice^® makes for easy transfer to a variety of analysis programs such as Excel and Matlab

Applications

• Wideband radar and pulsed RF signals
• Frequency agile communications
• Broadband satellite and microwave backhaul links
• Wireless LAN, WiGig, Bluetooth, Commercial Wireless
• Land Mobile Radio (LMR), APCO P25
• Long Term Evolution (LTE), Cellular

Wideband signal characterization

SignalVu helps you easily validate wideband designs and characterize wideband spectral events using an MSO/DPO5000, DPO7000, or DPO/DSA/MSO70000 Series digital oscilloscope. Users can easily switch between the SignalVu application and the oscilloscope's user interface to optimize the collection of wideband signals.

Trigger

SignalVu software works seamlessly with the oscilloscope allowing users to utilize all of its powerful triggering capabilities. The ability to trigger on time- and amplitude-varying events of interest is paramount in wideband system design, debug, and validation. The Tektronix oscilloscopes' trigger systems allow selection of virtually all trigger types on both A and B trigger events whether they be transition, state, time, or logic qualified triggers. Once triggered, SignalVu processes the acquisition for analysis in multiple domains.

Powerful oscilloscope triggers allow the user to capture only the relevant portion of wideband signals. Pinpoint trigger functions such as combining A and B events with Edge with Holdoff can capture a pulse train during a specific transmitter mode of operation.

Capture

Capture once - make multiple measurements without recapturing. All signals in an acquisition bandwidth are recorded into the oscilloscope's deep memory. Up to four channels can be captured simultaneously; each of which can be independently analyzed by SignalVu software. Channels can be RF, I and Q, or differential inputs. Users can also apply math functions to the acquisition prior to analysis by SignalVu. Acquisition lengths vary depending upon the selected capture bandwidth - up to 25 ms can be captured on a single channel with the MSO/DPO5000 Series, up to 12.5 ms can be acquired on a single channel with the DPO7000 Series, and up to 2.5 ms can be captured on a single channel with the DPO/DSA/MSO70000 Series. Significantly longer capture times can be realized with lower oscilloscope sample rates.

Using the FastFrame segmented memory feature in SignalVu enables you to capture events of interest, such as low duty cycle pulsed signals, while conserving acquisition memory. Using multiple trigger events, FastFrame captures and stores short-duration, bursty signals and passes them to SignalVu vector signal analysis functions. Capturing thousands of frames is possible, so long-term trends and changes in the bursty signal can be analyzed.

Once captured into memory, SignalVu provides detailed analysis in multiple domains. The spectrogram display (left panel) shows the frequency of a 500 MHz wide LFM pulse changing over time. By selecting the point in time in the spectrogram during the On time of the pulse, the chirp behavior can be seen as it sweeps from low to high (upper right panel).

Analyze

SignalVu RF and vector signal analysis software uses the same analysis capabilities found in the RSA5000 Series real-time spectrum analyzers. SignalVu advances productivity for engineers working on components or in wideband RF system design, integration, and performance verification, or operations engineers working in networks, or spectrum management. In addition to spectrum analysis, spectrograms display both frequency and amplitude changes over time. Time-correlated measurements can be made across the frequency, phase, amplitude, and modulation domains. This is ideal for signal analysis that includes frequency hopping, pulse characteristics, modulation switching, settling time, bandwidth changes, and intermittent signals.

SignalVu can process RF, I and Q, and differential I and Q signals from any one of the four available oscilloscope inputs. Math functions applied by the oscilloscope are also utilized by SignalVu allowing users to apply custom filtering prior to vector signal analysis.

The Microsoft Windows environment makes this multidomain analysis even easier with an unlimited number of analysis windows, all time-correlated, to provide deeper insight into signal behavior. A user interface that adapts to your preferences (keyboard, front panel, touch screen, and mouse) makes learning SignalVu easy for both first-time users and experienced hands.

Time-correlated, multidomain view provides a new level of insight into design or operational problems not possible with conventional analysis solutions. Here, the hop patterns of a narrowband signal can be observed using Spectrogram (lower right) and its hop characteristics can be precisely measured with Frequency vs Time display (lower left). The time and frequency responses can be observed in the two top views as the signal hops from one frequency to the next.

Options tailored for your wideband applications

SignalVu RF and vector signal analysis software is available for all MSO/DPO5000, DPO7000, and DPO/DSA/MSO70000 Series oscilloscopes and offers options to meet your specific application, whether it be wideband radar characterization, broadband satellite, or spectrum management. SignalVu Essentials (Opt. SVE) provides the fundamental capability for all measurements and is required for pulse analysis (Opt. SVP), settling time (Opt. SVT), digital modulation analysis (Opt. SVM), flexible OFDM analysis (Opt. SVO, not offered on MSO/DPO5000), and AM/FM/PM Modulation and Audio Measurements (Opt. SVA).

Wideband satellite and point-to-point microwave links can be directly observed with SignalVu analysis software. Here, General Purpose Digital Modulation Analysis (Opt. SVM) is demodulating a 16QAM backhaul link running at 312.5 MS/s.

Settling time measurements (Opt. SVT) are easy and automated. The user can select measurement bandwidth, tolerance bands, reference frequency (auto or manual), and establish up to 3 tolerance bands vs. time for Pass/Fail testing. Settling time may be referenced to external or internal trigger, and from the last settled frequency or phase. In the illustration, frequency settling time for a hopped oscillator is measured from an external trigger point from the device under test.

WLAN transmitter testing

With the WLAN measurement options, you can perform standards-based transmitter measurements in the time, frequency, and modulation domains.

• Option SV23 supports IEEE 802.11a, b, g, j and p signals
• Option SV24 supports IEEE 802.11n 20 MHz and 40 MHz SISO signals
• Option SV25 supports IEEE 802.11ac 20/40/80/160 MHz SISO signals

The table below described the modulation formats and frequency bands of IEEE 802.11 WLAN signals

The Frequency Band (Freq Band(s)) provides the minimum requirement for the bandwidth of the oscilloscope to use.

Inside SignalVu, the WLAN presets make the EVM, Constellation and SEM measurements push-button. The WLAN RF transmitter measurements are defined by the IEEE 802.11- 2012 revision of the standard and listed below with the reference to the section and the limit to reach.

WiGig IEEE802.11ad transmitter testing

Option SV30 provides WiGig IEEE802.11ad standard transmitter measurements. Used together with the DPO77002SX, it delivers industry’s best accurate signal quality measurement at 60GHz. It allows you to automatically detect the packet start, synchronize to preamble using the Golay codes in the short training field and demodulate preamble, header, and payload separately. These different fields are color coded in the User Interface. This option also measures EVM in each of the packet fields per the standard, and decodes the header packet information. In addition RF power, Received Channel Power Indicator, Frequency error, IQ DC origin offset, IQ Gain and Phase imbalance are reported in the Summary display. Pass/Fail results are reported using customizable limits and the presets make the test set-up push-button. Both Control PHY and Single Carrier PHY are supported and the measurements listed above can be done at RF or at IF. For further insight into the signal, you can also visualize the EVM spread across the analyzed packet with color codes differentiating fields and color coded demodulated symbols in tabular form with an option to traverse to the start of each field for easier navigation.

DPO77002SX SV30 provides industry best EVM accuracy. It allows easy setup to perform transmitter measurements including time overview of the bursts, spectrum, constellation diagram, decoded burst information and EVM measurements.

Bluetooth transmitter testing

With option SV27, you can perform Bluetooth SIG standard-based transmitter RF measurements in the time, frequency, and modulation domains. Option SV27 supports Basic Rate and Low Energy Transmitter measurements defined by Bluetooth SIG Test Specification RF.TS.4.2 for Basic Rate and RF-PHY.TS.4.2 for Bluetooth Low Energy. Option SV27 also automatically detects Enhanced Data Rate packets, demodulates them and provides symbol information.

Pass/Fail results are provided with customizable limits and the Bluetooth presets make the different test set-ups push-button.

Below is a summary of the measurements that are automated with option SV27 (unless noted):

• Bluetooth Low Energy Transmitter Measurements
  • Output power at NOC TRM-LE/CA/01/C and at EOC TRM-LE/CA/02/C
  • In-band emission at NOC TRM-LE/CA/03/C and at EOC TRM-LE/CA/04/C
  • Modulation characteristics TRM-LE/CA/05/C
  • Carrier frequency offset and drift at NOC TRM-LE/CA/06/C and at EOC TRM-LE/CA/07/C

• Basic Rate Transmitter Measurements
  • Output power TRM/CA/01/C
  • Power Density TRM/CA/02/C (no preset)
  • Power Control TRM/CA/03/C (no preset)
  • Tx output Spectrum – Frequency Range TRM/CA/04/C (no preset)
  • Tx output spectrum - 20dB Bandwidth TRM/CA/05/C
  • Tx output spectrum - Adjacent Channel Power TRM/CA/06/C
  • Modulation characteristics TRM/CA/07/C
  • Initial carrier frequency tolerance TRM/CA/08/C
  • Carrier frequency-drift TRM/CA/09/C

The following additional information is also available with SV27: symbol table with color coded field information, constellation, eye diagram, frequency deviation vs time with highlighted packet and octet, frequency offset and drift detailed table as well as packet header field decoding. Markers can be used to cross-correlate the time, vector and frequency information.

LTE FDD and TDD base station transmitter RF testing

Option SV28 enables the following LTE measurements:

• Cell ID

• Channel Power

• Occupied Bandwidth

• Adjacent Channel Leakage Ratio (ACLR)

• Spectrum Emission Mask (SEM)

• Transmitter Off Power for TDD

There are four presets to accelerate pre-compliance testing and determine the Cell ID. These presets are defined as Cell ID, ACLR, SEM, Channel Power and TDD Toff Power. The measurements follow the definition in 3GPP TS Version 12.5 and support all base station categories, including picocells and femtocells. Pass/Fail information is reported and all channel bandwidths are supported.

The Cell ID preset displays the Primary Synchronization Signal (PSS) and the Secondary Synchronization Signal (SSS) in a Constellation diagram. It also provides Frequency Error.

The ACLR preset measures the E-UTRA and the UTRA adjacent channels, with different chip rates for UTRA. ACLR also supports Noise Correction based on the noise measured when there is no input. Both ACLR and SEM will operate in swept mode (default) or in faster single acquisition if the instrument has enough acquisition bandwidth.

Measurement functions

The Advanced Signal Analysis package (Opt. SVP) provides 27 individual measurements to automatically characterize long pulse trains. An 500 MHz wide LFM chirp centered at 1 GHz is seen here with measurements for pulses 1 through 10 (lower right). The shape of the pulse can be seen in the Amplitude vs. Time plot shown in the upper left. Detailed views of pulse #8's frequency deviation and parabolic phase trajectory are shown in the other two views.

Settling time measurements (Opt. SVT) are easy and automated. The user can select measurement bandwidth, tolerance bands, reference frequency (auto or manual), and establish up to 3 tolerance bands vs. time for Pass/Fail testing. Settling time may be referenced to external or internal trigger, and from the last settled frequency or phase. In the illustration, frequency settling time for a hopped oscillator is measured from an external trigger point from the device under test.