PicoVNA 106
Sku: PIC-VNA-106
Price: R183235,25
A low-cost, professional-grade 6 GHz VNA for both lab and field use
Product Information
PicoVNA 6 GHz Vector Network Analyzer
High performance, portability and low cost
- 300 kHz to 6 GHz operation
- High speed of > 5000 dual-port s-parameters per second
- ‘Quad RX’ four-receiver architecture for optimal accuracy
- 118 dB dynamic range at 10 Hz bandwidth
- 0.005 dB RMS trace noise at bandwidth of 140 kHz
- Compact half-rack, lightweight package
- PC-controlled over USB from a Microsoft Windows interface
- Reference plane offsetting and de-embedding
- Time domain and port impedance transformations
- Tabular and graphic print and save formats, including Touchstone
- P1dB, AM to PM, and stand-alone signal generator utilities
- Fully accessible, guided 8 and 12-term calibration processes
- 6 calibration modes, including unknown through and connected DUT isolation
- Calibration and check standards with data for confident measurements
Making vector network analysis accessible
Today's microwave measuring instruments need to be straightforward, accurate, portable and affordable. No longer restricted to specialists, they are now used by scientists, educators, surveyors, inspectors, engineers and technicians in radio and gigabit data applications. Now Pico Technology has applied its expertise in microwave sampling oscilloscopes and time domain transmission and reflectometry to bring you a USB vector network analyzer.
The PicoVNA 106 is a professional USB-controlled, laboratory grade vector network instrument of unprecedented performance, portability and affordability. Despite its small size and low cost, the instrument boasts a ‘Quad RX’ four-receiver architecture to eliminate the uncorrectable errors, delays and fragility of three-receiver designs with internal transfer switches.
The PicoVNA 106 offers exceptional dynamic range of 118 dB and only 0.005 dB RMS trace noise at its maximum operating bandwidth of 140 kHz. It can also gather all four s-parameters at every frequency point in just 190 µs; in other words a 500 point 2-port .s2p Touchstone file in less than one tenth of a second. The cost is so low that the PicoVNA 106 could even be used as a cost-effective high-dynamic-range scalar network analyzer! It's affordable in the classroom, small business and even amateur workshop, yet capable in the microwave expert's laboratory.
Vector network analysis everywhere
With all these advantages, the PicoVNA 106 is ideal for field service, installation test and classroom applications. Its remote automation interface extends its use to applications such as:
- Test automation or the OEM needing to integrate a reflectometry or transmission measurement core, in:
- Electronics component, assembly and system, and interface/interconnect ATE (cable, PCB and wireless)
- Material, geological, life-science and food science tissue imaging or penetrating scan and radar applications
- Inspection, test, characterization or calibration in the manufacture, distribution and service center industries
- Broadband cable and harness test at manufacture, installation and fault over life
- Antenna matching and tuning
PicoVNA 106 features
‘Quad RX’ four-receiver architecture
In a VNA a swept sine-wave signal source is used to sequentially stimulate the ports of the interconnect or device under test. The amplitude and phase of the resultant transmitted and reflected signals appearing at both VNA ports are then received and measured. To wholly characterize a 2-port device under test (DUT), six pairs of measurements need to be made: the amplitude and phase of the signal that was emitted from both ports, and the amplitude and phase of the signal that was received at both ports for each source. In practice this can be achieved with a reasonable degree of accuracy with a single source, a transfer switch and two receivers; the latter inputs being switched through a further pair of transfer switches. Alternatively three receivers can be used with an additional input transfer switch or, as in the PicoVNA, four receivers can be used. Using four receivers eliminates the receiver input transfer switch errors (chiefly leakage and crosstalk) that cannot be corrected. These residual errors are always present in two- and three-receiver architectures and lead to lower accuracy than that of the Quad RX design.
Support for 8 and 12-term calibration and the unknown thru
Almost all vector network analyzers are calibrated for twelve error sources (six for each signal direction). This is the so-called 12-term calibration, which experienced VNA users are used to performing fairly regularly. In a four-receiver design some error sources are so reduced that 8-term calibration becomes possible, along with an important and efficient calibration technique known as the unknown thru. This gives the ability to use any thru interconnect (including the DUT) during the calibration process, vastly simplifying the procedure and reducing the number of costly calibration standards that need to be maintained.
Advanced vector network analyser users will be pleased to know that internal a-wave and b-wave data is made available for export under a diagnostic facility. Amongst others, Transfer switch error terms can therefore be derived.
Bias-Ts
Bias-Ts are often not provided, or available as costly extras, on other VNAs. Use the PicoVNA 106’s built-in bias-Ts to provide a DC bias or test stimulus to active devices without the complexity and cost of external DC-blocks. The bias is supplied from external power supplies or test sources routed to the SMB connectors adjacent to each VNA port.
Test cables and calibration standards
A range of RF and Microwave accessories are available from Pico Technology. Test cables and calibration standards have particular significance to the overall performance of a VNA, so we recommend that you select your accessories carefully. Cables and standards are often the weakest links in a VNA measurement, generally contributing significantly to measurement uncertainty despite their high cost. At the lowest levels of uncertainty, costs can be significant and measurements can be compromised by seemingly quite minor damage or wear. For these reasons, many customers hold both premium-grade items for calibration, reference or measurement standards, and standard-grade items as working or transfer standards and cables. Pico Technology can now offer cost-effective solutions in both grades.
Phase- and amplitude-stable test leads
Two test cable types and grades are recommended and provided by Pico Technology. Both of high quality, with robust and flexible construction and stainless steel connectors, the main difference between them is the stability of their propagation velocity and loss characteristic when flexed; that is, the degree to which a measurement could change when the cables are moved or formed to a new position. Cables are specified in terms of flatness and phase variation at up to 6 GHz when a straight cable is formed as one 360° turn around a 10 cm mandrel.
| Receiver characteristics | |||||
|---|---|---|---|---|---|
| Parameter | Value | Conditions | |||
| Measurement bandwidth | 140 kHz, 70 kHz, 35 kHz, 15 kHz, 10 kHz, 5 kHz, 1 kHz, 500 Hz, 100 Hz, 50 Hz, 10 Hz | ||||
| Average displayed noise floor |
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Relative to the test signal level set to maximum power after an S21calibration. Ports terminated as during the isolation calibration step. |
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| Dynamic range | See graphs (typical, excludes crosstalk) | 10 Hz bandwidth Maximum (+6 dBm) test power No averaging |
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| Temperature stability, typical | 0.02 dB/ °C for F < 4 GHz 0.04 dB/ °C for F ≥ 4 GHz |
Measured after an S21 calibration | |||
| Trace noise, dB RMS |
|
201-point sweep covering 1 MHz to 6 GHz. Test power set to 0 dBm. |
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| Measurement uncertainty | See table below | Test level of –3 dBm No averaging Bandwidth 10 Hz Ambient temperature equal to the calibration temperature. A 12 error term calibration is assumed carried out with a good quality 3.5 mm calibration kit capable of achieving the performance specified. |
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| Spurious responses | –76 dBc typical, –70 dBc max. | The main spurious response occurs at close to (2 x RF + 1.3) MHz, where RF is the test frequency in MHz. For example, when testing a bandpass filter with a centre frequency of, say 1900 MHz, an unwanted response will occur around 949.35 MHz. There may also be spurious responses close to (3 x RF + 2.6) MHz. In all known cases the levels will be as stated. | |||
| Measurement uncertainty – value | |||||
|---|---|---|---|---|---|
| Reflection measurements | Transmission measurements | ||||
| Freq. range | Magnitude | Phase | Freq. range | Magnitude | Phase |
| –15 dB to 0 dB | +0 dBm to +6 dBm | ||||
| < 2 MHz | 0.7 | 8° | < 2 MHz | 0.4 | 6° |
| > 2 MHz | 0.5 | 4° | > 2 MHz | 0.2 | 2° |
| –25 dB to –15 dB | |||||
| < 2 MHz | 0.8 | 10° | < 2 MHz | 0.2 | 2° |
| > 2 MHz | 1.0 | 6° | > 2 MHz | 0.1 | 1° |
| –30 dB to –25 dB | |||||
| < 2 MHz | 3.0 | 20° | < 2 MHz | 0.5 | 8° |
| > 2 MHz | 2.5 | 15° | > 2 MHz | 0.3 | 4° |
| < 2 MHz | 2.0 | 15° | |||
| > 2 MHz | 1.5 | 12° | |||
| Test port characteristics | |||||
|---|---|---|---|---|---|
| Load match |
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| Source match |
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| Directivity |
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| Crosstalk |
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10 Hz bandwidth Maximum (+6 dBm) test power No averaging |
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| Maximum input level | +10 dBm, typ | 1 dB compression | |||
| Maximum input level | +23 dBm | No damage | |||
| Impedance | 50 Ω | ||||
| Connectors | Type N, female | ||||
| Bias-T input characteristics | ||
|---|---|---|
| Maximum current | 250 mA | |
| Maximum DC voltage | ±15 V | |
| Current protection | Built-in resettable fuse | |
| DC port connectors | SMB(m) | |
| Sweep I/O characteristics | ||
|---|---|---|
| Sweep trigger output voltage | Low: 0 V to 0.8 V High: 2.2 V to 3.6 V |
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| Sweep trigger input voltage | Low: –0.1 V to 1 V High: 2.0 V to 4 V |
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| Sweep trigger input voltage | ±6 V | No damage |
| Sweep trigger in/out connectors | BNC female on back panel | |
| Measuring functions | ||
|---|---|---|
| Measuring parameters | S11, S21, S22, S12 P1dB, 1 dB gain compression AM-PM conversion factor |
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| Error correction | 12 error term full S-parameter correction (insertable DUT) 12 error term full S-parameter correction (non-insertable DUT) 8 error term full S-parameter unknown thru correction (non-insertable DUT) S11 (1-port correction) De-embed (2 embedding networks may be specified), impedance conversion S21 (normalize, normalize + isolation) S21 (source match correction + normalize + isolation) Averaging, smoothing Hanning and Kaiser–Bessel filtering on time-domain measurements Electrical length compensation (manual) Electrical length compensation (auto) Effective dielectric constant correction |
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| Display channels | 4 channels | |
| Traces | 2 traces per display channel | |
| Display formats | Amplitude (logarithmic and linear) Phase, Group Delay, VSWR, Real, Imaginary, Smith Chart, Polar, Time Domain |
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| Memory trace | One per display channel | |
| Limit lines | 6 segments per channel (overlap allowed) | |
| Markers | 8 markers | |
| Marker functions | Normal, Δ marker, fixed marker, peak / min. hold, 3 dB and 6 dB bandwidth | |
| Sweep functions | ||||||||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Sweep type | Linear sweep CW sweep (timed sweep) Power sweep (P1dB utility) |
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| Sweep times |
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10 MHz to 6 GHz, 201-point sweep. For other trace lengths and resolution bandwidths the sweep time is approximately: |
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| Number of sweep points, VNA mode | 51, 101, 201, 401, 801, 1001, 2001, 4001, 5001, 6001, 7001, 8001, 9001,10001 | |||||||||||||||||||
| Number of sweep points, TDR mode | 512, 1024, 2048, 4096 | |||||||||||||||||||
| Signal source characteristics | ||||
|---|---|---|---|---|
| Frequency range | 300 kHz to 6.0 GHz | |||
| Frequency setting resolution | 10 Hz | |||
| Frequency accuracy | 10 ppm max | With ambient of 23 ±3 °C | ||
| Frequency temperature stability | ±0.5 ppm/ºC max | Over the range +15 °C to +35 °C | ||
| Harmonics | –20 dBc max | With test power set to < –3 dBm | ||
| Non-harmonic spurious | –40 dBc typical | |||
| Phase noise (10 kHz offset) | –90 dBc/Hz [0.3 MHz to 1 GHz] –80 dBc/Hz [1 GHz to 4 GHz] –76 dBc/Hz [> 4 GHz] |
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| Test signal power |
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| Power setting resolution | 0.1 dB | |||
| Power setting accuracy | ±1.5 dB | |||
| Reference input frequency | 10 MHz ±6 ppm | |||
| Reference input level | 0 ±3 dBm | |||
| Reference output level | 0 ±3 dBm | |||
| Miscellaneous | |
|---|---|
| Controlling PC data interface | USB 2.0 |
| Support for third party test software | Dynamic Link Library (DLL) as part of user interface software |
| External dimensions (mm) | 286 x 174 x 61 (L x W x H) Excluding connectors |
| Weight | 1.85 kg |
| Temperature range (operating) | +15 °C to +40 °C |
| Temperature range (storage) | –20 °C to +50 °C |
| Humidity | 80% max, non-condensing |
| Vibration (storage) | 0.5 g, 5 Hz to 300 Hz |
| Power source and current | +12 to +15 V DC, 22 W |
| Power source connector | 5.5 mm diameter hole, 2.1 mm diameter centre contact pin. Centre pin is positive. |
| Host PC requirements | Microsoft Windows 7, 8 or 10 2 GB RAM or more |
| Warranty | 3 years |